Molecular compounds and complexes. V. Crystallography of equimolar aromatic hydrocarbon:l-<i>X</i>-2,4,6-trinitrobenzene molecular compounds. Crystal structure of fluoranthene: picryl bromide, polymorph I

Herbstein, F. H.; Kaftory, Menahem

doi:10.1107/s0567740875002117

Cited by 25 publications

(5 citation statements)

References 9 publications

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“…In the DTA curve there is a sharp peak a t 163°C indicating the melting point of the material. This value is in good agreement with the value available in the literature (162°C) [12] and the experimentally determined value (160°C). The sharpness of the endothermic peak shows good degree of crystallinity of the material [14].…”

Section: Resultssupporting

confidence: 91%

“…This paper reports the synthesis, solubility, growth aspect, linear, non linear, optical and the thermal properties of the title compound, whose SHG efficiency has been estimated to be 0.4 times that of m-nitro aniline [11]. The crystal belongs to the monoclinic system with the unit cell dimensions a=14.4Å, b=8.92 Å, c=6.85 Å, β=102° and space group C 2 [12].…”

Section: Introductionmentioning

confidence: 99%

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Synthesis, crystal growth, spectral, thermal and optical properties of acenaphthene picrate

Chandramohan

Bharathikannan

Kandhaswamy

et al. 2007

Cryst. Res. Technol.

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The crystalline material of acenaphthene picrate (ACP) was synthesized and the single crystals of the title compound grown by slow evaporation solution growth technique. The solubility of the complex compound was estimated using different solvents as chloroform, ethanol, (1:1) chloroform -acetone mixture. The material was characterized through elemental analysis; powder XRD, NMR and FTIR techniques. The various planes of reflection have been identified from the XRD powder pattern. The formation of the charge transfer complex was confirmed by UV-VIS spectroscopy. The thermal stability of the crystals was studied using TG/DTA analyses techniques. The second harmonic generation (SHG) of the material was confirmed by using Nd: YAG laser.

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Section: Resultssupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Synthesis, crystal growth, spectral, thermal and optical properties of acenaphthene picrate

Chandramohan

Bharathikannan

Kandhaswamy

et al. 2007

Cryst. Res. Technol.

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“…This observation suggests a compact association between the guest and the host. The occurrence of two alternative binding mechanisms between the FLT molecule and 2-HP-β/γ-CD can be attributed to the discrepancy in width between the two sides of the FLT molecule [46]. The 2-HP-β-CD cone-shaped cavity forces the FLT to insert itself with its benzene ringside (Figure S6) to maximize the binding constant and minimize the steric hindrance.…”

Section: Molecular Dynamic Simulationsmentioning

confidence: 99%

Polyaromatic Hydrocarbon Inclusion Complexes with 2-Hydroxylpropyl-β/γ-Cyclodextrin: Molecular Dynamic Simulation and Spectroscopic Studies

Alsadun,

Alfadil,

Elbashir

et al. 2024

Molecules

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In aqueous and solid media, 2-HP-β/γ-CD inclusion complexes with poly aromatic hydrocarbon (PAH) Phenanthrene (PHN), Anthracene (ANT), Benz(a)pyrene (BaP), and Fluoranthene (FLT) were investigated for the first time. The inclusion complexes were characterized and investigated using fluorescence and 1HNMR spectroscopy. The most prevalent complexes consisting of both guests and hosts were those with a 1:1 guest-to-host ratio. The stability constants for the complexes of PHN with 2-HP-β-CD and 2-HP-γ-CD were 85 ± 12 M−1 and 49 ± 29 M−1, respectively. Moreover, the stability constants were found to be 502 ± 46 M−1 and 289 ± 44 M−1 for the complexes of ANT with both hosts. The stability constants for the complexes of BaP with 2-HP-β-CD and 2-HP-γ-CD were (1.5 ± 0.02) × 103 M−1 and (9.41 ± 0.03) × 103 M−1, respectively. The stability constant for the complexes of FLT with 2-HP-β-CD was (1.06 ± 0.06) × 103 M−1. However, FLT was observed to form a weak complex with 2-HP-γ-CD. Molecular dynamic (MD) simulations were used to investigate the mechanism and mode of inclusion processes, and to monitor the atomic-level stability of these complexes. The analysis of MD trajectories demonstrated that all guests formed stable inclusion complexes with both hosts throughout the duration of the simulation time, confirming the experimental findings. However, the flexible Hydroxypropyl arms prevented the PAHs from being encapsulated within the cavity; however, a stable exclusion complex was observed. The main forces that influenced the complexation included van der Waals interactions, hydrophobic forces, and C–H⋯π interaction, which contribute to the stability of these complexes.

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“…Because of their electron-donating properties, naphthalene and its methyl derivatives are able to form more or less stable EDA complexes with picric acid, with sharp melting points [5]. Compounds which form this kind of complex usually give a solid-liquid system with a compound which has a competitive melting point.…”

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confidence: 99%

“…

Experimental

Materials

Chemically pure picric acid (2,4,6-TNF) (POCh, Gliwice) was dissolved in hot water and neutralized with a saturated solution of sodium carbonate.

…”

mentioning

confidence: 99%

Thermal investigation of solid-liquid equilibrium in the naphthalene (and some dimethyl derivatives)-picric acid systems

Kotula¹,

Rabczuk²

1980

Journal of Thermal Analysis

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The equilibria of the naphthalene-picric acid and the 2,3-and 2,6-dimethylnaphthalene-picric acid systems were subjected to thermal investigation.The naphthalene-picric acid system was earlier investigated by Kremann, Sapozhnikow and others [1,5]. In view of the divergence of their data, reinvestigation of this system was considered necessary. Experimental MaterialsChemically pure picric acid (2,4,6-TNF) (POCh, Gliwice) was dissolved in hot water and neutralized with a saturated solution of sodium carbonate. The sodium salt was treated with hot dilute sulfuric acid to give picric acid (m.p. 122.6 "~) of 99.7 % purity (determined by gas-chromatography).2,3-dimethylnaphthalene (2,3-DMN) and 2,6-dimethylnaphthalene (2,6-DMN) (BDH) were purified by rectification using a high-efficiency rectifying column to give 2,3-DMN (m.p. 105 ~ of 99.98 % purity and 2,6-DMN (m.p. 114.4 ~ of 99.9(~ )/o purity (determined by gas-chromatography).Naphthalene (POCh, Gliwice) was heated with bentonite and purified by rectification to give a product of 99.99 % purity with m.p. 80.8 ~ Apparatus and procedure 5 g samples of mixtures which differed in composition by weight in steps of 10 were prepared for measurements and ground to a uniform mass.Differential thermal (DTA) curves were recorded by means of a Paulik-PaulikErdey derNatograph, using 0.3 g samples in the smallest platinum crucible. The heating rate was 0.9 ~ per rain. in the range 20-1500 ~ The reference substance was Al20 3.Crystal decay temperature examination by Hill's method [3] as modified by Swierczek [4] was applied as a supplementary measurement. 4 g samples of mixtures of the same compositions as above were used. The heating rate near the melt-3 ~. Thermal Anal. 19, 1980

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Molecular compounds and complexes. V. Crystallography of equimolar aromatic hydrocarbon:l-X-2,4,6-trinitrobenzene molecular compounds. Crystal structure of fluoranthene: picryl bromide, polymorph I

Cited by 25 publications

References 9 publications

Synthesis, crystal growth, spectral, thermal and optical properties of acenaphthene picrate

Synthesis, crystal growth, spectral, thermal and optical properties of acenaphthene picrate

Polyaromatic Hydrocarbon Inclusion Complexes with 2-Hydroxylpropyl-β/γ-Cyclodextrin: Molecular Dynamic Simulation and Spectroscopic Studies

Thermal investigation of solid-liquid equilibrium in the naphthalene (and some dimethyl derivatives)-picric acid systems

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