Molecular self-assembly of 1D infinite polyiodide helices in a phenanthrolinium salt

Poręba, Tomasz; Świątkowski, Marcin; Kruszyński, Rafał

doi:10.1039/d0dt04042h

Cited by 7 publications

(17 citation statements)

References 82 publications

(88 reference statements)

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“…They are thought to enhance the mechanical performance and the thermal stability of polyiodides and, as recently shown, to modulate their conduction properties. I···I interactions, in addition to being an opportunity for semantic considerations, are the connectors that can make solid-state conduction feasible and efficient based on a Grotthuss-like mechanism, , which requires the preservation of orbital overlap along the iodine chains, a phenomenon favored by high iodine density. ,, Nonetheless, it has been shown that the physical properties, that is, electrical conductivity and thermal stability, of polyiodide chains are also affected by the supramolecular interactions they experience in the crystals . These details form a basis of information that can aid in the design of high-performance polyiodide-based solid-state conductors, which are of currently great practical interest for the development of new devices, especially for the preparation of solar cells , and batteries. , …”

Section: Introductionmentioning

confidence: 99%

Assembly of Polyiodide Networks with Cu(II) Complexes of Pyridinol-Based Tetraaza Macrocycles

et al. 2021

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Polyiodide networks are currently of great practical interest for the preparation of new electronic materials. The participation of metals in the formation of these networks is believed to improve their mechanical performance and thermal stability. Here we report the results on the construction of polyiodide networks obtained using Cu(II) complexes of a series of pyridinol-based tetraazacyclophanes as countercations. The assembly of these crystalline polyiodides takes place from aqueous solutions on the basis of similar structural elements, the [CuL] 2+ and [Cu(H –1 L)] + (L = L2 , L2-Me , L2-Me 3 ) complex cations, so that the peculiarities induced by the increase of N-methylation of ligands, the structural variable of ligands, can be highlighted. First, solution equilibria involving ligands and complexes were analyzed (potentiometry, NMR, UV–vis, ITC). Then, the appropriate conditions could be selected to prepare polyiodides based on the above complex cations. Single-crystal XRD analysis showed that the coordination of pyridinol units to two metal ions is a prime feature of these ligands, leading to polymeric coordination chains of general formula {[Cu(H –1 L)]} n n + (L = L2-Me , L2-Me 3 ). In the presence of the I – /I 2 couple, the polymerization tendency stops with the formation of [(CuL)(CuH –1 L)] 3+ (L = L2-Me , L2-Me 3 ) dimers which are surrounded by polyiodide networks. Moreover, coordination of the pyridinol group to two metal ions transforms the surface charge of the ring from negative to markedly positive, generating a suitable environment for the assembly of polyiodide anions, while N-methylation shifts the directional control of the assembly from H-bonds to I···I interactions. In fact, an extended concatenation of iodine atoms occurs around the complex dimeric cations, the supramolecular I···I interactions become shorter and shorter, fading into stronger forces dominated by the orbital overlap, which is promising for effective electronic materials.

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Section: Introductionmentioning

confidence: 99%

Assembly of Polyiodide Networks with Cu(II) Complexes of Pyridinol-Based Tetraaza Macrocycles

et al. 2021

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“…1,2 In most cases, polyiodides can be described with the general formula I 2m+n n− , in which n and m represent the number of iodide anions (I − ) and of iodine molecules (I 2 ), respectively. 3,4 In the solid state, polyiodides display a vast diversity of compositions and structures, ranging from the simplest and linear I 3 − and I 4 2− to the V-shaped I 5 − and zigzag I 23 3− anions, complex two-dimensional (2D) networks, and three-dimensional (3D) cage-like structures, such as I 9…”

Section: ■ Introductionmentioning

confidence: 99%

“…Though simple, this procedure can be varied in many ways depending on the solvent used and on the nature and size of the cation associated with the iodide or triiodide anion. 3 As a rule of thumb, large cations favor the formation of extended polyiodide chains in the solid state, 3,4,12 and various supramolecular interactions such as hydrogen or halogen bonds, 11,13−15 caging, 16,17 and anion•••π 18,19 concur to stabilize the chains within the crystalline material. 2 Polyiodides, though extensively studied, constitute a class of materials still relatively poorly understood, and their intrinsic structural unpredictability has prompted further research in this direction, 20 in particular, to rationalize the formation of polyiodide infinite chains, which are, in turn, sought for their potential applications as electrolytes in solar cells, 21−24 electrochemical devices, 25−27 and optical devices, 26,28 among others.…”

Section: ■ Introductionmentioning

confidence: 99%

Embroidering Ionic Cocrystals with Polyiodide Threads: The Peculiar Outcome of the Mechanochemical Reaction between Alkali Iodides and Cyanuric Acid

D’Agostino

Shemchuk

Taddei

et al. 2022

Crystal Growth & Design

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We report here the preparation and structural characterization of a series of new crystalline materials obtained by mechanochemical mixing of cyanuric acid (CA) and alkali halides (LiI, NaI, and KI) in the presence of molecular iodine, namely, the isomorphous catena-poly[tetra(cyanuric acid)•lithium tetraiodide], n[CA 4 •LiI 4 ], and catena-poly[tetra(cyanuric acid)•sodium tetraiodide], n[CA 4 •NaI 4 ], featuring threedimensional (3D) cationic frameworks able to segregate linear, infinite n[I 4 − ] chains in their squared open channels and the layered solid [CA•KI 3 ] 2 •I 2 •2H 2 O characterized by alternating sheets of (i) hydrated potassium cations and CA molecules and (ii) I 3 − anions and discrete I 2 molecules. The combination of X-ray diffraction (XRD), Raman spectroscopy, and thermal analyses allowed us to elucidate the compound's structural features and to discuss the effect of cation size on the stoichiometry and architecture of the three ionic cocrystals (ICCs).

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“…3,18,19 Recently, infinite PI chains stabilized with planar pyrroloperylene and phenantrolinium cations were reported. 20,21 In general, the stability of higher PIs decreases with the higher number of iodine atoms. In turn, larger PI units require bulky (soft) cations to stabilize them.…”

Section: ■ Introductionmentioning

confidence: 99%

“…PIs exhibit a great structural diversity in the crystalline state. − Their discrete chains range from the minimal I 3 – unit up to I 29 3– . Besides, a number of I 2 ···I n m – adducts are reported in the Cambridge Structural Database (CSD) v.5.40 (Figure S1) which can be regarded as intermediate products of the addition reaction to form higher PIs. ,, Recently, infinite PI chains stabilized with planar pyrroloperylene and phenantrolinium cations were reported. , …”

Section: Introductionmentioning

confidence: 99%

Pressure-Aided Stabilization of Pyramidal Polyiodides

et al. 2021

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Crystals of N-propylurotropinium heptaiodide, containing unusual pyramidal [I 3 − •2I 2 ] moieties, have been subjected to controlled temperature and pressure changes. Thermogravimetric analysis revealed their complex thermochemistry at elevated temperature, which includes the formation of stable intermediate polyiodides. X-ray diffraction experiments on decomposition products elucidated the thermal breakdown pathways and the role of the crystalline environment on their thermostability. The electrical conductivity has been shown to drop significantly as the parent crystal is depleted of iodine. The thermostabilizing role of compression and its relation to the supramolecular architecture emerges from high-pressure synchrotron X-ray diffraction data. High pressure prevents the studied polyiodide from decomposition at high temperature and significantly raises its melting point. Additionally, compression fosters the stepwise catenation between diiodine and triiodide units, up to the formation of I 14 2− moieties at ca. 4 GPa. The observed effects were related to the pressure-induced changes in the crystal ionic strength and vibrational entropy, as well as the increase in I−I bond covalency.

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Molecular self-assembly of 1D infinite polyiodide helices in a phenanthrolinium salt

Abstract: Iodine atoms align into a 1D polymeric polyiodide chain, stabilized with the surrounding phenanthrolinium cations.

Cited by 7 publications

References 82 publications

Assembly of Polyiodide Networks with Cu(II) Complexes of Pyridinol-Based Tetraaza Macrocycles

Assembly of Polyiodide Networks with Cu(II) Complexes of Pyridinol-Based Tetraaza Macrocycles

Embroidering Ionic Cocrystals with Polyiodide Threads: The Peculiar Outcome of the Mechanochemical Reaction between Alkali Iodides and Cyanuric Acid

Pressure-Aided Stabilization of Pyramidal Polyiodides

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