Methylammonium Tetrel Halide Perovskite Ion Pairs and Their Dimers: The Interplay between the Hydrogen-, Pnictogen- and Tetrel-Bonding Interactions

Abstract: The structural stability of the extensively studied organic–inorganic hybrid methylammonium tetrel halide perovskite semiconductors, MATtX3 (MA = CH3NH3+; Tt = Ge, Sn, Pb; X = Cl, Br, I), arises as a result of non-covalent interactions between an organic cation (CH3NH3+) and an inorganic anion (TtX3−). However, the basic understanding of the underlying chemical bonding interactions in these systems that link the ionic moieties together in complex configurations is still limited. In this study, ion pair models … Show more

“…This accords with the second feature in ref . k The UV–vis absorption bands of the HaBD chromophore may experience a shift to shorter wavelengths; − the binding energies of the peaks associated with X with the X-ray photoelectron spectrum (XPS) of the R−X···Y complex shift to lower energies relative to unbonded X, in accordance with the eighth and tenth features, respectively, in ref . l A bond path and a bond critical point between HaBD X and HaBA Y may be found when an electron density topology analysis based on the quantum theory of atoms in molecules (QTAIM) , is carried out, together with the appearance of other charge density-based signatures such as those associated with the sign and magnitude of the Laplacian of the charge density and the total energy density at bond critical points . This may be in accordance with the sixth feature in ref . m Isosurface volumes (colored greenish, blue, or blue-green between HaBD X and HaBA Y, representative of attractive interactions ,,, ) may be seen if a noncovalent index analysis (NCI) based on reduced density gradients is performed; − similar isosurface features may also emerge when an independent gradient model (IGM), , an IGM based on Hirshfeld partition of molecular density (IGMH), or an interaction region indicator (IRI) analysis is performed. , Feature l may fail in some chemical systems, especially in the weak bonding regime, ,,− but the isosurface analysis is expected to recover inter- and/or intramolecular interaction between interacting atomic basins. ,, n At least some transfer of charge density from the frontier HaBA orbital to the frontier HaBD orbital may occur (viz. from a (filled) lone-pair type orbital ( n ) to an empty σ*-/π*-type anti-bonding orbital); when the transfer of charge density between the orbitals is significant, the formation of a dative (covalent) interaction is likely .…”

“…An analysis of the geometric feature alone is insufficient to determine whether the I···F close contact is a HaB. However, as we will show below, and have demonstrated recently elsewhere, the I···F close contact could be regarded as HaB given that the interaction between the anion and the cation in the crystal is likely to play an important role in polarizing the electrostatic field of the anion; the induction of a positive potential on the surface of the I in C 6 ­H 5 ­F 5 ­I – along the C–I bond extension may occur, which shall interact attractively with the lateral portion of F in a neighboring C 6 H 5 F 5 I – . This speculative scenario for the occurrence of halogen bonding in the crystal is very different from that found in the crystals of tri­fluoro­meth­yl-tetra­fluoro-iodine (CF 7 I) and penta­fluoro­phen­yl-tetra­kis­(fluoro)­iodine (C 6 F 9 I) ( vide infra ).…”

“…81 A positive σ-hole on covalently bonded halogen X may be introduced in an anion in the presence of cation that enables it to engage attractively with a HaBA site Y, developing a halogen bond between them, as observed in the case of a tetrel derivative in an anion. 119 Note 17. An attractive noncovalent interaction between an electrophilic (or nucleophilic) region on a halogen atom in one molecular entity and an electrophilic (or nucleophilic) region in the same or a neighboring interacting molecular entity may not be considered to be a halogen bond if both carry the same charge polarity (see Notes 2, 6, and 7 and the definition).…”

“…The highly negative σ-hole may become less negative because of electron-withdrawing substituents at the peripheral sites of a halogenated molecule . A positive σ-hole on covalently bonded halogen X may be introduced in an anion in the presence of cation that enables it to engage attractively with a HaBA site Y, developing a halogen bond between them, as observed in the case of a tetrel derivative in an anion …”

Definition of the Halogen Bond (IUPAC Recommendations 2013): A Revisit

“…This accords with the second feature in ref . k The UV–vis absorption bands of the HaBD chromophore may experience a shift to shorter wavelengths; − the binding energies of the peaks associated with X with the X-ray photoelectron spectrum (XPS) of the R−X···Y complex shift to lower energies relative to unbonded X, in accordance with the eighth and tenth features, respectively, in ref . l A bond path and a bond critical point between HaBD X and HaBA Y may be found when an electron density topology analysis based on the quantum theory of atoms in molecules (QTAIM) , is carried out, together with the appearance of other charge density-based signatures such as those associated with the sign and magnitude of the Laplacian of the charge density and the total energy density at bond critical points . This may be in accordance with the sixth feature in ref . m Isosurface volumes (colored greenish, blue, or blue-green between HaBD X and HaBA Y, representative of attractive interactions ,,, ) may be seen if a noncovalent index analysis (NCI) based on reduced density gradients is performed; − similar isosurface features may also emerge when an independent gradient model (IGM), , an IGM based on Hirshfeld partition of molecular density (IGMH), or an interaction region indicator (IRI) analysis is performed. , Feature l may fail in some chemical systems, especially in the weak bonding regime, ,,− but the isosurface analysis is expected to recover inter- and/or intramolecular interaction between interacting atomic basins. ,, n At least some transfer of charge density from the frontier HaBA orbital to the frontier HaBD orbital may occur (viz. from a (filled) lone-pair type orbital ( n ) to an empty σ*-/π*-type anti-bonding orbital); when the transfer of charge density between the orbitals is significant, the formation of a dative (covalent) interaction is likely .…”

“…An analysis of the geometric feature alone is insufficient to determine whether the I···F close contact is a HaB. However, as we will show below, and have demonstrated recently elsewhere, the I···F close contact could be regarded as HaB given that the interaction between the anion and the cation in the crystal is likely to play an important role in polarizing the electrostatic field of the anion; the induction of a positive potential on the surface of the I in C 6 ­H 5 ­F 5 ­I – along the C–I bond extension may occur, which shall interact attractively with the lateral portion of F in a neighboring C 6 H 5 F 5 I – . This speculative scenario for the occurrence of halogen bonding in the crystal is very different from that found in the crystals of tri­fluoro­meth­yl-tetra­fluoro-iodine (CF 7 I) and penta­fluoro­phen­yl-tetra­kis­(fluoro)­iodine (C 6 F 9 I) ( vide infra ).…”

“…81 A positive σ-hole on covalently bonded halogen X may be introduced in an anion in the presence of cation that enables it to engage attractively with a HaBA site Y, developing a halogen bond between them, as observed in the case of a tetrel derivative in an anion. 119 Note 17. An attractive noncovalent interaction between an electrophilic (or nucleophilic) region on a halogen atom in one molecular entity and an electrophilic (or nucleophilic) region in the same or a neighboring interacting molecular entity may not be considered to be a halogen bond if both carry the same charge polarity (see Notes 2, 6, and 7 and the definition).…”

“…The highly negative σ-hole may become less negative because of electron-withdrawing substituents at the peripheral sites of a halogenated molecule . A positive σ-hole on covalently bonded halogen X may be introduced in an anion in the presence of cation that enables it to engage attractively with a HaBA site Y, developing a halogen bond between them, as observed in the case of a tetrel derivative in an anion …”

Definition of the Halogen Bond (IUPAC Recommendations 2013): A Revisit

“…The characteristics of the π-hole can be understood based on positive or negative signs of the electrostatic potential. A region on a molecular entity can have either V S,max > 0 (or V S,min > 0) if the π-hole is electrophilic (electron density deficient) [52,122,123], or V S,max < 0 (or V S,min < 0) if nucleophilic (electron density rich) [47,55,56]. When such a situation is encountered, the former and latter characteristics signify the presence of positive and negative π-holes, respectively, and appear on the outer extensions around the covalently bonded atom (or molecular plane) orthogonal to the R-A bond axis [55].…”

Halogen Bond via an Electrophilic π-Hole on Halogen in Molecules: Does It Exist?