Photochemistry of Aryl Pentazoles: para-Methoxyphenylpentazole

Insight into the Stability of Pentazolyl Derivatives based on Covalent Bond

Pentazole is regarded as a unique inorganic molecule that possess organic heterocyclic structure. Therefore, the research on pentazolyl derivatives represents a cutting-edge direction in both contemporary inorganic chemistry and heterocyclic chemistry. Moreover, their synthesis is regarded as the most significant research topic in the field of energetic materials due to the great potential of pentazolyl derivatives to breakthrough the energy bottleneck of CHNO-based energetic materials. However, synthesizing pentazolyl derivatives is challenging. To provide a theoretical support for the synthesis, we conducted theoretical studies on six single-ring pentazolyl derivatives with different functional groups. The results suggest that derivatization reduces the bond strength and weakens the aromaticity of the pentazolate ring. Further analysis showed that derivatization mainly affects the π aromaticity of the pentazolate ring, and ultimately causing poor stability of the pentazolyl derivatives. Among the six derivatives investigated in this study, fluoro pentazole (cyclo-N5-F) and hydroxyl pentazole (cyclo-N5-OH) possess good aromaticity, which is similar to the reported cyclo-N5-NCHN(CH3)2. Further calculations show that the kinetic stability of cyclo-N5-OH is higher than that of cyclo-N5-F. These results collectively indicate that cyclo-N5-OH is a promising candidate for synthesizing single-ring pentazolyl derivatives.

Synthesis mechanism of four metallic Cyclo-N5- energetic materials: A theoretical Perspective

In the past five years, over 20 types of cyclo-N5- energetic materials (EMs) have been successfully synthesized. Metallic cyclo-N5- EMs exhibit higher density and performance compared to non-metallic cyclo-N5- EMs. However, the mechanisms for such metallic cyclo-N5- EMs remain unexplored. Herein, we performed a thorough quantum chemistry study on the mechanistic pathway for the cyclo-N5- trapped by metal cations in four cyclo-N5- EMs: [Na(H2O) (N5)] · 2H2O, [M(H2O)4(N5)2] · 4H2O (M = Mn, Fe, and Co), by density functional theory methods and transition state theory. During the synthesis process, the cyclo-N5- in the precursor hybrid aromatic compound is susceptible to electrophilic attack by metal cations. This attack disrupts the hydrogen bond interaction surrounding the cyclo-N5-, ultimately leading to the formation of either an ionic bond or a coordination bond between the metal cation and the cyclo-N5-, resulting in an electrophilic substitution reaction. In addition, solvent effects reduce the energy of the ionic bond, thereby promoting the reaction. Our findings will provide valuable insights for future route design and contribute to enhancing the synthesis yield of cyclo-N5- EMs in both theoretical and experimental aspects.

Symmetrical cyclo-N5- hydrogen bonds: stabilization mechanism of four non-metallic cyclo-pentazolate energetic salts

Pairing different cations (R⁺) to stabilize cyclo-N₅^- is the main synthesis path for non-metallic cyclo-pentazolate (cyclo-N₅^-) salts. As novel energetic materials (EMs), crystalline packing-force of cyclo-N₅^- salts has been a puzzle, and whether cyclo-N₅^- is protonated also is a controversial issue. In this paper, four non-metallic cyclo-N₅^- salts, PHAC, N₂H₅N₅, NH₃OHN₅, and NH₄N₅, are quantitatively studied by coupling first-principle method and bond-strength analyzing technology. Different from the traditional CHON-EMs (molecular crystal) and azide-EMs (ionic crystal), the four salts are stabilized by 3D hydrogen bond (HB) networks. One new type of hydrogen bond, protonated HB (p-H, R-H⋯N₅^-), is discovered to be a key stabilizing factor for cyclo-N₅^-. Proton competition mechanism between R and cyclo-N₅^- in p-H HB showed that cyclo-N₅^- cannot be protonated into HN₅. In general, p-H HB can be adopted to estimate the stability of novel non-metallic cyclo-N₅^- EMs. Such findings have great significance for future design and performance prediction of novel cyclo-N₅^- EMs in both theoretical and experimental aspects.

A carbon-free inorganic-metal complex consisting of an all-nitrogen pentazole anion, a Zn(ii) cation and H2O

A carbon-free inorganic-metal complex [Zn(H₂O)₄(N₅)₂]·4H₂O was synthesized by the ion metathesis of [Na(H₂O)(N₅)]·2H₂O solution with Zn(NO₃)₂·6H₂O. The complex was well characterized by IR and Raman spectroscopy, elemental analysis (EA), powder X-ray diffraction (PXRD), and differential scanning calorimetry (DSC). The structure of the complex was confirmed by single-crystal X-ray crystallography and a Zn(ii) ion is coordinated in a quadrilateral bipyramid environment in which the axial position is formed by two nitrogen atoms (N1) from two pentazolate rings (cyclo-N₅^-) and the equatorial plane is formed by four oxygen atoms (O1) from four coordinated water molecules. The thermal analysis of [Zn(H₂O)₄(N₅)₂]·4H₂O reveals that although water plays an important role in stabilizing cyclo-N₅^-, dehydration does not cause immediate decomposition of the anion. However, cyclo-N₅^- decomposed into N₃^- and N₂ gas at 107.9 °C (onset). Based on its chemical compatibility and stability, the complex exhibits promising potential as a modern environmentally-friendly energetic material.

Recent advances in the syntheses and properties of polynitrogen pentazolate anion cyclo-N5− and its derivatives

This review summarizes recent developments and advances in pentazole chemistry, including substituted-pentazole precursors, strategies for the preparation of pentazolate anion, derivatives of pentazolate anion and their bonding properties.

Joint experimental and theoretical studies of the surprising stability of the aryl pentazole upon noncovalent binding to β-cyclodextrin

Large enhancement in the thermal stability of aryl pentazole is confirmed experimentally and theoretically through the formation of a host–guest complex with β-cyclodextrin