Dual-Redox-Sites Enable Two-Dimensional Conjugated Metal–Organic Frameworks with Large Pseudocapacitance and Wide Potential Window

Zhang, Panpan, Wang, Mingchao, Liu, Yannan, Yang, Sheng, Wang, Faxing, Li, Yang, Chen, Guangbo, Li, Zichao, Wang, Gang, Zhu, Minshen, Dong, Renhao, Yu, Minghao, Schmidt, Oliver G., Feng, Xinliang

26 July 2022

Advanced supercapacitor electrodes require the development of materials with dense redox sites embedded into conductive and porous skeletons. Two-dimensional (2D) conjugated metal–organic frameworks (c-MOFs) are attractive supercapacitor electrode materials due to their high intrinsic electrical conductivities, large specific surface areas, and quasi-one-dimensional aligned pore arrays. However, the reported 2D c-MOFs still suffer from unsatisfying specific capacitances and narrow potential windows because large and redox-inactive building blocks lead to low redox-site densities of 2D c-MOFs. Herein, we demonstrate the dual-redox-site 2D c-MOFs with copper phthalocyanine building blocks linked by metal-bis(iminobenzosemiquinoid) (M2[CuPc(NH)8], M = Ni or Cu), which depict both large specific capacitances and wide potential windows. Experimental results accompanied by theoretical calculations verify that phthalocyanine monomers and metal-bis(iminobenzosemiquinoid) linkages serve as respective redox sites for pseudocapacitive cation (Na+) and anion (SO42–) storage, enabling the continuous Faradaic reactions of M2[CuPc(NH)8] occurring in a large potential window of −0.8 to 0.8 V vs Ag/AgCl (3 M KCl). The decent conductivity (0.8 S m–1) and high active-site density further endow the Ni2[CuPc(NH)8] with a remarkable specific capacitance (400 F g–1 at 0.5 A g–1) and excellent rate capability (183 F g–1 at 20 A g–1). Quasi-solid-state symmetric supercapacitors are further assembled to demonstrate the practical application of Ni2[CuPc(NH)8] electrode, which deliver a state-of-the-art energy density of 51.6 Wh kg–1 and a peak power density of 32.1 kW kg–1.

info:eu-repo/classification/ddc/540

ddc:540

Dynamic Covalent Chemistry for Accelerated Photoswitch Discovery and Photoswitchable Core-Shell Metal-Organic Frameworks

Mutruc, Dragos

07 July 2022

Photoschalter sind Moleküle, die eine reversible lichtgesteuerte Umwandlung zwischen zwei Zuständen mit unterschiedlichen Eigenschaften durchlaufen. In den letzten zehn Jahren hat der Einbau dieser photochromen Moleküle in intelligente, auf Stimuli ansprechende Materialien zunehmende Aufmerksamkeit erregt, da sie die einzigartige Fähigkeit bieten, makroskopische Eigenschaften mit einem externen optischen Stimulus reversibel zu verstärken und zu verändern. Die begrenzte Leistung von Photoschaltern in festen Medien bleibt eine Herausforderung. In diesem Zusammenhang werden in dieser Arbeit zwei wichtige Aspekte näher untersucht. Erstens der Prozess der Entwicklung neuer Photoschalter mit maßgeschneiderten Eigenschaften und zweitens die Implementierung von Photoschaltern in feste Materialien und die damit verbundenen Herausforderungen. Im ersten Teil dieser Arbeit wurde Dynamisch-kovalente Chemie (DCC) verwendet, um die Entdeckung und Entwicklung einer neuartigen Klasse von Photoschaltern mit drei Zuständen zu beschleunigen. Die dynamische Natur der zentralen Doppelbindung von α-Cyanodiarylethenen wurde genutzt, um ein thermodynamisches Gleichgewicht mit anderen Arylacetonitrilen herzustellen. Die entwickelte Methode kombiniert eine schnelle Diversifizierung mit einer Rasterung auf spezifische Eigenschaften, die durch einen externen Stimulus aufgedeckt werden, und ermöglicht die effiziente Untersuchung der Beziehung zwischen Struktur und den zugehörigen Eigenschaften. Im zweiten Teil der Arbeit wird die Entwicklung und die Synthese eines Zweikomponenten-Kern-Schale-MOFs mit einem internen nicht-funktionalisierten Kompartiment, das von einer dünnen photoschaltbaren Außenschale bedeckt ist, vorgestellt. Diese Strategie ermöglicht ein effizientes Schalten des Chromophors und die resultierende dünne „intelligente“ Schale fungiert als modulare kinetische Barriere für die molekulare Gastdiffusion in das Material, die durch Licht gesteuert werden kann. / Photoswitches are molecules that undergo a reversible light-triggered conversion between two states with different properties. In the past decade, the incorporation of these photochromic molecules in smart stimuli-responsive materials has gained increased attention as it offers the unique ability to reversibly amplify and change macroscopic properties with an external optical stimulus. The limited performance of photoswitches in solid mediums remains a challenge. In this context two important aspects are studied in more detail in this thesis. First, the process of developing new photoswitches with tailored properties and second, the implementation of photoswitches in solid materials and the challenges associated with it. In the first part of this thesis dynamic covalent chemistry (DCC) was used to accelerate the discovery and development of a novel three-state photoswitch class. The dynamic nature of the central double bond of α-cyanodiarylethenes was exploited to establish a thermodynamic equilibrium with other arylacetonitriles. The developed DCC tool combines fast and efficient diversification with screening for specific photochemical properties revealed by an external stimulus, enabling the rapid study of the relationship between structure and the associated properties. The second part of this thesis summarizes the design and synthesis of a two-component core-shell MOF with an internal non-functionalized compartment covered by a thin photoswitchable outer shell. This strategy allows efficient switching of the chromophore and the resulting thin “smart” shell acts as a modular kinetic barrier for molecular guest diffusion into the material that can be controlled by light.

Photoschalter

Metal-organische Gerüststrukturen

dynamisch kombinatorische Bibliotheken

photoswitches

Metal-organic frameworks

stimuli-responsive smart materials

dynamic combinatorial libraries

547 Organische Chemie

ddc:547

Fluorescence Studies of Metal Organic Frameworks Based on the TATB Ligand, Synthesis and Characterization of an Fe4S4 Analogue and Organic Radicals

Bunkowske, Beatrice A.

12 December 2011

No description available.

Inorganic Chemistry

Metal Organic Frameworks

Fluorescence

TATB Ligand

Iron Sulfur Clusters

Organic Radicals

Transition Metals

Lanthanide Metals

Thiocynate Ligands

Magnetic Properties

MULTI-FUNCTIONAL CARBON-BASED NANOMATERIALS FOR ENERGY CONVERSION AND STORAGE

Dai, Quanbin

25 January 2022

No description available.

Chemistry

Materials Science

Cooperative Assembly of 2D-MOF Nanoplatelets into Hierarchical Carpets and Tubular Superstructures for Advanced Air Filtration

Schwotzer, Friedrich, Horak, Jacob, Senkovska, Irena, Schade, Elke, Gorelik, Tatiana E., Wollmann, Philipp, Anh, Mai Lê, Ruck, Michael, Kaiser, Ute, Weidinger, Inez M., Kaskel, Stefan

11 June 2024

Clean air is an indispensable prerequisite for human health. The capture of small toxic molecules requires the development of advanced materials for air filtration. Two-dimensional nanomaterials offer highly accessible surface areas but for real-world applications their assembly into well-defined hierarchical mesostructures is essential. DUT-134(Cu) ([Cu2(dttc)2]n, dttc=dithieno[3,2-b : 2′,3′-d]thiophene-2,6-dicarboxylate]) is a metal–organic framework forming platelet-shaped particles, that can be organized into complex structures, such as millimeter large free-standing layers (carpets) and tubes. The structured material demonstrates enhanced accessibility of open metal sites and significantly enhanced H2S adsorption capacity in gas filtering tests compared with traditional bulk analogues.

info:eu-repo/classification/ddc/540

ddc:540

Metal-Organic Frameworks as Heterogenous Photocatalysts for the Production of Solar Fuels

Cabrero Antonino, María

09 November 2021

[ES] La presente tesis doctoral se ha basado en el estudio del uso de MOFs como fotocatalizadores para la producción de combustibles solares. Específicamente, los fotocatalizadores basados en MOF se han utilizado para la reacción de descomposición del agua y la reducción de CO2 en ausencia de agentes de sacrificio o disolventes orgánicos. MIL-125(Ti)-NH2 se puede utilizar como fotocatalizador para la reacción de descomposición del agua en presencia de UV-Vis o irradiación natural de la luz solar. La actividad de este material se puede potenciar mediante el uso de Pt y NPs de RuOx como co-catalizadores. Además, la actividad fotocatalítica de MIL 125(Ti)-NH2 se puede mejorar mediante un tratamiento de plasma de oxígeno que introduce defectos estructurales dando lugar a un material optimizado para catalizar la reacción de descomposición del agua. La presente tesis ha mostrado por primera vez la posibilidad de utilizar MOFs como fotocatalizadores para la metanación de CO2. En particular, un Zn-MOF y un Ti-MOF, MOF(Zn)-1 y MIP 208 respectivamente, se pueden utilizar como fotocatalizadores para promover la metanación de CO2 en condiciones de reacción suaves. Además, la actividad fotocatalítica de estos MOFs se incrementa en presencia de pequeñas NPs de Cu2O y, especialmente, por NPs de RuOx en la estructura de estos materiales. Es de destacar que el material compuesto por NPs de RuOx soportadas en MIL-125(Ti)-NH2 puede considerarse un fotocatalizador de referencia para la metanación de CO2 mediada por energía solar y en flujo continuo. / [CA] La present tesi doctoral s'ha basat en l'estudi de l'ús de MOFs com a fotocatalitzadors per a la producció de combustibles solars. Específicament, els fotocatalitzadors basats en MOF s'han utilitzat per a la reacció de descomposició de l'aigua i la reducció de CO¿ en absència d'agents de sacrifici o dissolvents orgànics. MIL-125(Ti)-NH2 es pot utilitzar com fotocatalitzador per a la reacció de descomposició de l'aigua sota UV-Vis o irradiació natural de la llum solar i la seua activitat pot ser augmentada mitjançant l'ús de Pt i NPs de RuOx com co catalitzadors. A més, l'activitat fotocatalítica de MIL-125(Ti)-NH2 es pot millorar mitjançant un tractament de plasma d'oxigen que introdueix defectes estructurals resultant en un material optimitzat per a la reacció de descomposició de l'aigua. La present tesi ha mostrat per primera vegada la possibilitat d'utilitzar MOFs com fotocatalizador per a la metanació de CO¿. En particular, un Zn-MOF y un Ti MOF, MOF(Zn)-1 y MIP-208 respectivament, es poden utilitzar com fotocatalitzadors per a promoure la metanació de CO¿ en condicions de reacció suaus. A més, l'activitat fotocatalítica d'aquests MOFs pot ser realçada per la presència de xicotetes NPs de Cu2O i, especialment, per les NPs de RuOx en l'estructura d'aquestos materials. És de destacar que el material composat per NPs de RuOx suportades en MIL-125(Ti)-NH2 es pot considerar un fotocatalitzador de referència per a la metanació de CO2 amb energia solar i en flux continu. / [EN] The present doctoral thesis studied the use of MOFs as photocatalysts to produce solar fuels. MOF-based photocatalysts were used for overall water splitting and CO2 reduction in the absence of sacrificial agents or organic solvents. MIL 125(Ti)-NH2 can be used as photocatalyst for overall water splitting under both UV-Vis or natural sunlight irradiation. The activity of this material can be enhanced using Pt and RuOx NPs as co-catalysts. Also, the photocatalytic activity of pristine MIL 125(Ti)-NH2 can be enhanced by oxygen-plasma treatment, which introduces structural defects and produces an optimized material for overall water splitting. This thesis has shown for the first time the possibility of using MOFs as photocatalysts for CO2 methanation. More specifically, a Zn and Ti MOF materials, MOF(Zn)-1 and MIP-208 respectively, can be used as photocatalysts to promote CO2 methanation under mild reaction conditions. The photocatalytic activity of these MOFs can be enhanced in the presence of small Cu2O NPs, and, especially, RuOx NPs in their structure. RuOx NPs supported on MIL-125(Ti)-NH2 can be envisioned as a benchmark photocatalyst for solar-driven CO2 methanation in continuous-flow operations. / Cabrero Antonino, M. (2021). Metal-Organic Frameworks as Heterogenous Photocatalysts for the Production of Solar Fuels [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/176660

Oxidación fotocatalítica

Combustibles solares

Estructuras metal-orgánicas

Fotocatálisis heterogénea

Metanización de CO2

Solar fuels

Overall water splitting

CO2 Methanation

Heterogeneous photocatalysis

Metal-Organic frameworks

QUIMICA ORGANICA

Metal-Organic Hybrid Materials with Catalytic and Photocatalytic Applications

Melillo, Arianna

26 April 2022

[ES] La presente tesis doctoral ha centrado la atención en la síntesis de nuevos materiales MOFs obtenidos por intercambio post-sintético de MOFs descritos anteriormente o por heterounión de MOFs estables que tienen estructura UiO66. Estos materiales se han aplicado como fotocatalizadores para la prometedora reacción de división completa del agua que pretende obtener H2 y O2 en forma estequiométrica a partir de agua en ausencia de agentes sacrificantes o nanopartículas metálicas. El nuevo material UiO66 (Zr/Ce/Ti) mostró resultados sorprendentes para la reacción general de división del agua en ambas condiciones de luz UV-Visible e irradiación solar. También se obtuvieron resultados interesantes en el caso del nucleo-corteza UiO66(Zr)-NH225@UiO66(Ce) que, en presencia de agua, cuando se irradió con luz ultravioleta y con luz solar, permitió obtener 550 𝝁 mol*g- 1 de H2 y 350 𝝁 mol*g-1 de H2 en 24 h respectivamente, en las mismas condiciones de trabajo definidas para UiO66(Zr/Ce/Ti). En este trabajo de tesis se presentó por primera vez la posibilidad de reducir 4-NP a través de una metodología tándem que involucra primero la producción de H2 a partir de agua en presencia de metanol, como agente de sacrificio, y UiO66(Zr)-NH2, como fotocatalizador, y la posterior reducción de 4-NP a 4-AP. Por otro lado, se ha demostrado que los materiales defectuosos con estructura de UiO66 pueden reducir selectivamente los dobles enlaces polarizados X=Y en presencia de gas H2. / [CA] La present tesi doctoral ha centrat l'atenció en la síntesi de nous materials MOFs obtinguts per intercanvi post-sintètic de MOFs descrits anteriorment o per heterounió de MOFs estables que tenen estructura UiO66. Estos materials s'han aplicat com fotocatalitzadors per a la prometedora reacció de divisió completa de l'aigua que pretén obtindre H2 i O2 en forma estequiomètrica a partir d'aigua en absència d'agents sacrificants o nanopartícules metàl·liques. El nou material UiO66 (Zr/Ce/Ti) va mostrar resultats sorprenents per a la reacció general de divisió de l'aigua en ambdós condicions de llum UV-Visible i irradiació solar. També es van obtindre resultats interessants en el cas del core-shell UiO66 (Zr) - NH225@UiO66 (Ce) que, en presència d'aigua, quan es va irradiar amb llum ultravioleta i amb llum solar, va permetre obtindre 550 𝝁 mol*g-1 de H2 i 350 𝝁 mol*g-1 de H2 en 24 h respectivament, en les mateixes condicions de treball definides per a UiO66 (Zr/Ce/Ti). En este treball de tesi es va presentar per primera vegada la possibilitat de reduir 4-nitrofenol a través d'una metodologia tàndem que involucra primer la producció de H2 a partir d'aigua en presència de metanol, com a agent de sacrifici, i UiO66 (Zr) -NH2, com fotocatalizador, i la posterior reducció de 4-NP a 4-AP. D'altra banda, s'ha demostrat que els materials defectuosos amb estructura d'UiO66 poden reduir selectivament els dobles enllaços polaritzats X=Y en presència de gas H2. / [EN] The present doctoral thesis has focused the attention on the synthesis of new MOFs materials obtained either by post-synthetic interchange of previously described MOFs or by heterojunction of stable MOFs having UiO66 structure. These materials have been applied as photocatalysts for the promising Overall Water Splitting reaction which claims to obtain H2 and O2 stoichiometrically starting from water in the absence of sacrificial agents or deposited metals nanoparticles. The new material UiO66 (Zr/Ce/Ti) showed surprising results in both UV- Visible light and sunlight irradiation conditions. Interesting results were also obtained in the case of the core-shell named UiO66(Zr)-NH225@UiO66(Ce) which, in the presence of water, when irradiated with both ultraviolet and solar light, allowed to obtain 550 𝝁 mol*g-1 of H2 and 350 𝝁 mol*g-1 of H2 in 24 h respectively, in the same working conditions defined for UiO66 (Zr/Ce/Ti). In this thesis was presented, for the first time, the possibility of reducing 4NP through a tandem methodology which, first, involves the production of H2 from water in the presence of methanol as a sacrificial agent and UiO66(Zr)-NH2 as a photo-catalyst, and subsequent the 4 NP reduction to 4 AP. On the other hand, it has been shown that defective materials with UiO66 structure can selectively reduce polarized X=Y double bonds in the presence of H2 gas. / Melillo, A. (2022). Metal-Organic Hybrid Materials with Catalytic and Photocatalytic Applications [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/182744

Separación fotocatalítica del agua

Actividad fotocatalítica

Catálisis

Fotocatálisis

Marcos metalorgánicos (MOFs)

Heterocatálisis

Photocatalytic water splitting

Photocatalytic activity

Metal organic frameworks (MOFs)

Catalysis

Photocatalysis

Heterocatalysis

QUIMICA ORGANICA

A Logic Gate Based on a Flexible Metal–Organic Framework (JUK-8) for the Concomitant Detection of Hydrogen and Oxygen

Roztocki, Kornel, Bon, Volodymyr, Senkovska, Irena, Matoga, Dariusz, Kaskel, Stefan

22 May 2024

We present an autonomous, chemical logic gate based on a switchable metal–organic framework (MOF) composite, containing carbon nanoparticles and a Pt catalyst. The switchable MOF composite performs as AND logic gate. Hydrogen and oxygen gas streams serve as binary inputs. Catalytically formed water induces a structural transition (crystal volume expansion) of the MOF, and as a consequence, a detectable drop in conductance of the composite as a ‘true’ output only if both gases come in contact with the composite.

info:eu-repo/classification/ddc/540

ddc:540

info:eu-repo/classification/ddc/660

ddc:660

Homoleptic Co(II), Ni(II), Cu(II), Zn(II) and Hg(II) complexes of bis-(phenyl)-diisoindol-aza-methene

Gresser, Roland, Hoyer, Alexander, Hummert, Markus, Hartmann, Horst, Leo, Karl, Riede, Moritz

31 March 2014

The synthesis of five homoleptic transition metal complexes of bis-(phenyl)-diisoindol-aza-methene is described together with the optical, electrochemical and thermal properties of these compounds. Additionally, crystal structures for the Co and the Zn complex are reported. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

Metall-organische Gerüste

MOF

leichte Säuren

Energieübertragung

Bordipyrromethen-Farbstoffe

HSAB-Konzept

Basen

Dimer

metal-organic frameworks

soft acids

energy-transfer

BODIPY dyes

bases hsab

chemistry

hard

dimers

ddc:540

rvk:VA 1120

Polymères de coordination luminescents 1D et 2D avec des ligands rigides contenant du Pt(II) montrants des propriétés d’adsorption du CO2 / Luminescent 1D-and 2D-coordination polymers constructed with rigid Pt(II)-containing ligands exhibiting CO2 adsorption properties

Juvenal, Frank

January 2017

La conception de nouveaux matériaux fonctionnels a une longue histoire. Durant les deux dernières décennies, le domaine des polymères organiques et inorganiques a attiré l'attention des chercheurs. Plus important encore, les matériaux poreux tels que les Metal Organic Frameworks (MOFs), en anglais, Covalent Organic Frameworks (COFs), en anglais, ainsi que des polymères de coordination poreux sont maintenant étudiés de manière intensive en raison de leurs applications potentielles, comprenant le stockage de gaz, la séparation de gaz, la catalyse et la détection. D'un autre côté, les polymères contenant du Pt ont montré l'application potentielle dans les cellules solaires et les diodes électroluminescentes. Le mémoire est divisé en trois sections principales présentant des résultats nouveaux. Dans la première section, le chapitre 2 traite essentiellement de la formation de polymères de coordination (CP) avec des sels CuX (X = Cl, Br, I) et trans-[p-MeSC6H4C≡C-Pt(PMe3)2-C≡CC6H4SMe] (L1), soit dans le PrCN ou PhCN. Les polymères résultants sont soit 2D (bidimensionel) ou 1D (unidimensionel). Cependant, en presence de PrCN ou de PhCN, le CP 2D obtenu avec le CuBr n'a pas incorporé de solvant dans ses espaces vides. D'autre part, le CP 2D et le reste des CP 1D obtenus avaient soit des molécules de solvant de cristallisation dans leurs cavités ou coordonnés au cuivre sur la chaîne. Les unités cuivre-halogénures étaient soit des rhomboïdes Cu2X2 ou le cubane Cu4I4. Leurs mesures photophysiques en présence et en l'absence de molécules de solvant de cristallisation ont été effectuées. En outre, la porosité du CP a été évaluée par BET (N2 à 77 K). Le vapochromisme du CP 2D sans solvant et des CP 1D ont été étudiés, ainsi que les mesures de sorption du CO2 ont été effectuées. De plus, nous avons utilisé CuCN et L1 dans MeCN pour former de nouveaux CP’s. Ceci est rapporté dans la deuxième section, le chapitre 3. Le CP obtenu était inattendu : L1 s’est rompu et du cyanure CN‾ s’est coordonné sur le Pt. Ceci a conduit à la formation d’un CP 1D zigzag. Généralement, les CP sont formés avec L1 via des liens Cu-S ou/et Cu([éta]2-C≡C), mais pas dans le cas du CuCN qui lui forme une chaîne 1D (CuCN)n où le L1 rompu se lie avec cette chaîne via un lien Cu-N. Les propriétés photophysiques et de stabilité thermique ont été étudiées. La troisième section (Chapitre 4) traite d'une exploration des CP formés par la reaction des sels CuX (X = Cl, Br, I) et le trans-[p-MeSC6H4C≡C-Pt(PMe3)2-C≡CC6H4SMe] (L1) ou le trans-[p-MeSC6H4C≡C-Pt(PEt3)2-C≡CC6H4SMe] (L2) dans du MeCN afin de trouver des tendances. L'utilisation de L1 a donné lieu à un CP 2D ou 1D CPs avec le MeCN piégé à l'intérieur des cavités, il y a de l’espace vide. L2 a conduit uniquement à des CP 1D sans molecules de solvant de cristallisation. Des analyses thermogravimétriques, photophysique et des mesures d’adsorption de gaz (uniquement pour ceux avec du solvant) ont été étudiées. / Abstract: The design of new functional materials has a long history. For the past two decades, the field of organic and inorganic polymers has attracted attention of researchers. More importantly, porous materials such as Metal Organic Frameworks (MOFs), Covalent Organic Frameworks (COFs) as well as porous coordination polymers are now being intensively studied due to their potential applications including gas storage, gas separations, catalyst and sensing. On another hand, Pt-containing polymers have shown potential applications in solar cells and light emitting diodes. The masters’ thesis is mainly divided into three main sections presenting new results. In the first section; Chapter 2 mainly discusses the formation of coordination polymers with CuX salts (X= Cl, Br, I) and trans-[p-MeSC6H4C≡C-Pt(PMe3)2-C≡CC6H4SMe] (L1), in either PrCN or PhCN. The resulting polymers obtained were 2D (bidimensional) CPs or 1D (unidimensional) CPs in all cases. However, 2D CPs obtained when CuBr salt is used by either using PrCN or PhCN did not incorporate the solvents in their cavities. On the other hand, the 2D CP and the rest of 1D CPs obtained had either the crystallization molecules in the cavities or coordinated to the copper cluster. The copper-halide clusters were either the rhomboids Cu2X2 fragments or the step cubane Cu4I4. The photophysical measurements in the presence and absence of solvent crystallization molecules were performed. In addition, the porosity of the CPs was evaluated by adsorption isotherms. The vapochromism of the solvent-free 2D and 1D CPs were investigated as well as CO2 sorption measurements were perfomed. Furthermore, we then attempted to use CuCN and L1 in MeCN which is reported in the second section as Chapter 3. The obtained CP was unexpected as L1 broke and a cyanide (CN‾) ion coordinated to the Pt atom leading to the formation of zigzag 1D CP. The coordination bonds Cu-S or/and Cu([eta]2-C≡C) were generally observed with L1, but not in the CuCN case. Instead a 1D chain of (CuCN)n was made and the broken L1 now binds the chain via a Cu-N bond. The photophysical and thermal stability properties were studied. Lastly, the third section, Chapter 4 deals with a potential predictability of CP formation by using CuX salts (X= Cl, Br, I) and either trans-[p-MeSC6H4C≡C-Pt(PMe3)2-C≡CC6H4SMe] (L1) or trans-[p-MeSC6H4C≡C-Pt(PEt3)2-C≡CC6H4SMe] (L2) in MeCN as the solvent. The use of L1 resulted in either 2D or 1D CPs with the MeCN trapped inside of the cavities while L2 resulted in 1D CPs without MeCN being present in their cavities. The thermogravimetric, photophysical as well as gas sorption measurements (only for those with crystalisation molecules) were perfomed.

Metal Organic Frameworks (MOFs)

Polymères de coordination poreux

Covalent Organic Frameworks (COFs)

Clusters cuivre-halogénures

Vapochromisme

Adsorption de gaz

Porous coordination polymers

Copper-halide clusters

Vapochromism

Gas sorption measurements