74 research outputs found
Kinetic Control of Interpenetration in Fe-Biphenyl-4,4 '-dicarboxylate Metal-Organic Frameworks by Coordination and Oxidation Modulation
Phase control in the self-assembly of metalâorganic frameworks (MOFs) is often a case of trial and error; judicious control over a number of synthetic variables is required to select the desired topology and control features such as interpenetration and defectivity. Herein, we present a comprehensive investigation of self-assembly in the Feâbiphenyl-4,4â˛-dicarboxylate system, demonstrating that coordination modulation can reliably tune between the kinetic product, noninterpenetrated MIL-88D(Fe), and the thermodynamic product, two-fold interpenetrated MIL-126(Fe). Density functional theory simulations reveal that correlated disorder of the terminal anions on the metal clusters results in hydrogen bonding between adjacent nets in the interpenetrated phase and this is the thermodynamic driving force for its formation. Coordination modulation slows self-assembly and therefore selects the thermodynamic product MIL-126(Fe), while offering fine control over defectivity, inducing mesoporosity, but electron microscopy shows MIL-88D(Fe) persists in many samples despite not being evident by diffraction. Interpenetration control is also demonstrated using the 2,2â˛-bipyridine-5,5â˛-dicarboxylate linker; it is energetically prohibitive for it to adopt the twisted conformation required to form the interpenetrated phase, although multiple alternative phases are identified due to additional coordination of Fe cations to its N donors. Finally, we introduce oxidation modulationâthe use of metal precursors in different oxidation states from that found in the final MOFâto kinetically control self-assembly. Combining coordination and oxidation modulation allows the synthesis of pristine MIL-126(Fe) with BET surface areas close to the predicted maximum for the first time, suggesting that combining the two may be a powerful methodology for the controlled self-assembly of high-valent MOFs
Kinetic control of interpenetration in Fe-biphenyl-4,4â˛-dicarboxylate metal-organic frameworks by coordination and oxidation modulation
Phase control in the self-assembly of metal-organic frameworks (MOFs) is often a case of trial and error; judicious control over a number of synthetic variables is required to select the desired topology and control features such as interpenetration and defectivity. Herein, we present a comprehensive investigation of self-assembly in the Fe-biphenyl-4,4â˛-dicarboxylate system, demonstrating that coordination modulation can reliably tune between the kinetic product, non-interpenetrated MIL-88D(Fe), and the thermodynamic product, two-fold interpenetrated MIL-126(Fe). Density functional theory simulations reveal that correlated disorder of the terminal anions on the metal clusters results in hydrogen-bonding between adjacent nets in the interpenetrated phase and is the thermodynamic driving force for its formation. Coordination modulation slows self-assembly and therefore selects the thermodynamic product MIL-126(Fe), while offering fine control over defectivity, inducing mesoporosity, but electron microscopy shows MIL-88D(Fe) persists in many samples despite not being evident by diffraction. Interpenetration control is also demonstrated using the 2,2â˛-bipyridine-5,5â˛-dicarboxylate linker; it is energetically prohibitive for it to adopt the twisted conformation required to form the interpenetrated phase, although multiple alternative phases are identified due to additional coordination of Fe cations to its N-donors. Finally, we introduce oxidation modulation â the use of metal precursors in different oxidation states to that found in the final MOF â to kinetically control self-assembly. Combining coordination and oxidation modulation allows the synthesis of pristine MIL-126(Fe) with BET surface areas close to the predicted maximum for the first time, suggesting that combining the two may be a powerful methodology for the controlled self-assembly of high-valent MOFs
Low-valent iron: an Fe(I) ate compound as a building block for a linear trinuclear Fe cluster
A low-valent trinuclear iron complex with an unusual linear Fe(I)âFe(II)âFe(I) unit is presented. It is accessed in a rational approach using a salt metathesis reaction between a new anionic Fe(I) containing heterocycle and FeCl2. Its electronic structure was studied by single crystal XRD analysis, EPR and MĂśssbauer spectroscopy, and magnetic susceptibility measurements
Cooperative reduction by Ln2+ and Cp*â ions: synthesis and properties of Sm, Eu, and Yb complexes with 3,6-di-tert-butyl-o-benzoquinone
The first examples of samarium, europium, and ytterbium complexes with 3,6-di-tert-butyl-o-benzoquinone (3,6-dbbq) in the form of catecholate have been obtained by reactions of the quinone with the corresponding lanthanocenes, Image ID:c5dt03573b-t2.gif (n = 1 or 2) in solution. In the course of the reactions lanthanide ions lose one or two Cp* ligands, which take part in reduction of a quinone molecule into a catecholate anion (dbcat, 2â). As a result of the reactions, Sm and Yb clearly yield dimeric complexes [(LnCp*)2(dbcat)2], where each Ln ion loses one Cp* ligand. Eu forms a trimeric complex [(EuCp*)(Eu¡thf)2(dbcat)3], in which one Eu ion is coordinated by one Cp* ligand, while two Eu ions have lost all Cp* ligands and are coordinated by THF molecules instead. Magnetic properties corroborate the assignment of oxidation states made on the basis of single-crystal X-ray diffraction: all the quinone ligands are present in the catecholate state; both Sm/Yb ions in the dimers are in the +3 oxidation state, whereas the Eu trimer contains two Eu(II) and one Eu(III) ions. Cyclovoltammetry studies show the presence of two reversible oxidation waves for all complexes, presumably concerned with the redox transitions of the dbcat ligands
Bidirectional photoswitching of magnetic properties at room temperature: ligand-driven light-induced valence tautomerism
Valence tautomeric (VT) metal complexes are highly promising bistable molecular compounds for applications as molecular switches in molecular electronics and spintronics. Although VT species can be switched with light, the photoswitching in all reported systems requires very low temperatures (usually below 20 K) because photoinduced states are highly unstable at room temperature. The thermal instability hinders any practical application of these complexes in genuine devices. In this report, for the first time we demonstrate photoswitching of VT species and associated magnetic properties at room temperature. The bidirectional photoswitching in solution is due to cisâtrans photoisomerizable 4-styrylpyridine ligands deliberately integrated into cobalt dioxolene molecular complexes. The novel type of photoswitching has been coined Ligand-Driven Light-Induced Valence Tautomerism (LD-LIVT). The photoconversion of VT states of 28% has been achieved in solution at room temperature. The photoinduced states show extraordinary thermal stability for hours at room temperature, as compared to common nanoseconds reported previously. The switching proceeds at molecular level with the effective photoswitching rate of 3 Ă 1013 molecules per s under our conditions. Consequently, this work may open new horizons in applications of molecular switches based on VT metal complexes in molecular devices functioning at room temperature
Bidirectional photoswitching of magnetic properties at room temperature: ligand-driven light-induced valence tautomerism
Valence tautomeric (VT) metal complexes are highly promising bistable molecular compounds for applications as molecular switches in molecular electronics and spintronics. Although VT species can be switched with light, the photoswitching in all reported systems requires very low temperatures (usually below 20 K) because photoinduced states are highly unstable at room temperature. The thermal instability hinders any practical application of these complexes in genuine devices. In this report, for the first time we demonstrate photoswitching of VT species and associated magnetic properties at room temperature. The bidirectional photoswitching in solution is due to cisâtrans photoisomerizable 4-styrylpyridine ligands deliberately integrated into cobalt dioxolene molecular complexes. The novel type of photoswitching has been coined Ligand-Driven Light-Induced Valence Tautomerism (LD-LIVT). The photoconversion of VT states of 28% has been achieved in solution at room temperature. The photoinduced states show extraordinary thermal stability for hours at room temperature, as compared to common nanoseconds reported previously. The switching proceeds at molecular level with the effective photoswitching rate of 3 Ă 1013 molecules per s under our conditions. Consequently, this work may open new horizons in applications of molecular switches based on VT metal complexes in molecular devices functioning at room temperature
Reversible Shifting of a Chemical Equilibrium by Light: The Case of Keto-Enol Tautomerism of a β-Ketoester
Manipulating the
equilibrium between a ketone and an enol by exposure to light opens up ample
opportunities in material chemistry and photopharmacology since it allows one
to reversibly control the content of the enol tautomer, which acts as a
hydrogen atom donor, with high spatio-temporal and energy resolution. Although
tautomerization of β-ketoesters or their analogs was studied in numerous
papers, their light-induced reversible tautomerization to give thermally stable
enols (photoenolization) is an unexplored area. To shed light on this âblind
spotâ, we report an unprecedented property of diarylethene 2A assembled from fragments of photoactive dithienylethene and a
β-ketoester as part of the cyclohexenone bridge. In a pristine state, the
tautomeric equilibrium of 2 is
almost completely shifted towards the ketone. Photocyclization of the
hexatriene system results in a new equilibrium system containing a significant
fraction of the enol tautomer, both in polar and non-polar solvents. Due to the
considerable spectral separation (35 nm), the keto-enol tautomerization process
could be observed visually. The tendency of 2A to undergo light-induced enolization was proved by isolating a
related byproduct of photochemical 1,2-dyotropic rearrangement stabilized in the
enolic form. Our results provide a novel tool for controlling the keto-enol
tautomerism that might find use in the development of novel photocontrollable
processes
Spin Crossover Meets Diarylethenes: Efficient Photoswitching of Magnetic Properties in Solution at Room Temperature
A photoisomerizable
diarylethene-derived ligand, phen*, has been successfully introduced
into a spin-crossover ironÂ(II) complex, [FeÂ(H<sub>2</sub>BÂ(pz)<sub>2</sub>)<sub>2</sub>phen*] (<b>1</b>; pz =1-pyrazolyl). A ligand-based
photocyclization (photocycloreversion) in <b>1</b> modifies
the ligand field, which, in turn, results in a highly efficient paramagnetic
high-spin â diamagnetic low-spin (low-spin â high-spin)
transition at the coordinated Fe<sup>II</sup> ion. The reversible
photoswitching of the spin states, and thus the associated magnetic
properties, has been performed in solution at room temperature and
has been directly monitored by measuring the magnetic susceptibility
via the Evans method. The observed spin-state photoconversion in <b>1</b> exceeds 40%, which is the highest value for spin-crossover
molecular switches in solution at room temperature reported to date.
The photoexcited state is extraordinarily thermally stable, showing
a half-time of about 18 days in solution at room temperature. Because
of the outstanding photophysical properties of diarylethenes, including
single-crystalline photochromism, molecular switch <b>1</b> may
offer a promising platform for controlling the magnetic properties
in the solid state and ultimately at the single-molecule level with
light at room temperature
Spin Crossover Meets Diarylethenes: Efficient Photoswitching of Magnetic Properties in Solution at Room Temperature
A photoisomerizable
diarylethene-derived ligand, phen*, has been successfully introduced
into a spin-crossover ironÂ(II) complex, [FeÂ(H<sub>2</sub>BÂ(pz)<sub>2</sub>)<sub>2</sub>phen*] (<b>1</b>; pz =1-pyrazolyl). A ligand-based
photocyclization (photocycloreversion) in <b>1</b> modifies
the ligand field, which, in turn, results in a highly efficient paramagnetic
high-spin â diamagnetic low-spin (low-spin â high-spin)
transition at the coordinated Fe<sup>II</sup> ion. The reversible
photoswitching of the spin states, and thus the associated magnetic
properties, has been performed in solution at room temperature and
has been directly monitored by measuring the magnetic susceptibility
via the Evans method. The observed spin-state photoconversion in <b>1</b> exceeds 40%, which is the highest value for spin-crossover
molecular switches in solution at room temperature reported to date.
The photoexcited state is extraordinarily thermally stable, showing
a half-time of about 18 days in solution at room temperature. Because
of the outstanding photophysical properties of diarylethenes, including
single-crystalline photochromism, molecular switch <b>1</b> may
offer a promising platform for controlling the magnetic properties
in the solid state and ultimately at the single-molecule level with
light at room temperature
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