Yuxiang Daiab and
Yang Qi*ab
aInstitute of Materials Physics and Chemistry, School of Materials Science and Engineering, Northeastern University, Shenyang 110819, China. E-mail: qiyang@imp.neu.edu.cn
bKey Laboratory for Anisotropy and Texture of Materials, Ministry of Education, Northeastern University, Shenyang, 110819, China
First published on 25th January 2018
A reversible pressure-induced structural phase transition of 4-aminobenzonitrile was found at about 0.3 GPa by conducting in situ high-pressure synchrotron angle-dispersive X-ray diffraction (ADXRD) experiments. The discontinuous changes of Raman modes at 0.2 GPa confirmed the occurrence of phase transition. In situ high-pressure Raman spectra indicated that the molecular arrangement and intermolecular interactions changed abruptly. The process of this phase transition continued up to about 1.0 GPa. When the pressure reached 1.1 GPa, the initial N–H⋯N interaction transformed into a new weak hydrogen bond, which was enhanced by further compression. The ab initio calculations and Hirshfeld surfaces were used to illustrate the above views. This study gives an example that demonstrates that the pressure can induce the formation of hydrogen bonds, which contributes to the development of supramolecular chemistry.
At ambient conditions, 4-aminobenzonitrile (C7H6N2) crystals are of monoclinic P21/c symmetry (phase I).33 The amino group and the benzene ring of 4-aminobenzonitrile are almost co-planar with the dihedral angle of about 13°. Since the length of C–NH2 bond is short, the amino group is substantially in a triangular conformation. As shown in Fig. 1, 4-aminobenzonitrile molecules are attached by N–H⋯N interactions almost along the c-axis. Due to the geometrical characteristics of the molecular arrangement, only one hydrogen atom on the amino group of 4-aminobenzonitrile is possible to form the N–H⋯N hydrogen bond with the nitrogen atom on the cyano group. The distance of H⋯N in this N–H⋯N interaction is 2.527 Å, which is just a little longer than that of regular weak hydrogen bonds.1 Since the packing of molecules can be enhanced by accelerating pressure, it is very possible for 4-aminobenzonitrile to form N–H⋯N hydrogen bonds under high pressure. Sometimes, new hydrogen bonds may form after the original ones being broken by external pressure,10,34,35 but it is rare to observe the formation of hydrogen bonds from other weak non-covalent interactions.
Fig. 1 Crystal structure of 4-aminobenzonitrile under ambient conditions. The dash lines represent the N–H⋯N interactions between adjacent molecules. |
Moreover, the crystal structure will change with the formation of new hydrogen bonds. Furthermore, the continuous increase of the pressure can enhance the intensity of the weak and medium D–H⋯A hydrogen bonds (D and A denote the donor and acceptor of the hydrogen bond respectively), resulting in an extension of the D–H distance.36–38 Therefore, we took 4-aminobenzonitrile as an example to investigate its potential various changes of the N–H⋯N hydrogen bond and crystal structure by using in situ high-pressure Raman spectroscopy and synchrotron ADXRD combining with ab initio calculations in this study. As N–H⋯N hydrogen bonds widely exist in supramolecular materials,1,25 the results of this study can provide some new ideas to understand the formation and enhancement of weak hydrogen bonds in the supramolecular assembly at high pressure.
Raman measurements were made by a micro Raman system assembled with a thermo-electrically cooled CCD (Synbority, Horiba Jobin Yvon), a spectrometer (iHR 550, Horiba Jobin Yvon) and a 671 nm excitation laser. The beamline with a 0.6199 Å wavelength beam of BL15U1 in Shanghai Synchrotron Radiation Facility (SSRF) was used for in situ high-pressure ADXRD experiments.40 The CeO2 standard was used for calibration. The Fit2D software was used to process the ADXRD patterns collected by the Mar345 detector.41 The ADXRD patterns were further analyzed by using Materials Studio 5.0 to obtain detailed information on the crystal structure of 4-aminobenzonitrile at high pressure. Ab initio calculations of the high-pressure crystal structure were performed by using the pseudopotential plane wave method in the CASTEP package. The generalized gradient approximation of Perdew–Burke–Ernzerhof exchange correlation42–44 was used in the geometric optimization with a plane wave cutoff energy of 700 eV.
Fig. 2 Representative synchrotron XRD patterns of 4-aminobenzonitrile at high pressures: (a) from 1 atm to 2.0 GPa; (b) from 3.0 GPa to 6.2 GPa. The new peaks are marked by blue arrows. |
Fig. 3 (a) Reduced lattice constants from ADXRD experiments, (b) unit cell volume as a function of pressure. |
After further analysis, we obtained the evolution of the unit cell volume of 4-aminobenzonitrile crystals below 2 GPa (Fig. 3b). The results of the second-order Birch–Murnaghan equation fitting on the unit cell volume with compression were calculated by the free online program PASCal from http://pascal.chem.ox.ac.uk/:45 V0 = 638.19(5) Å3, B0 = 9.25(8) GPa, B′0 = 4 (fixed) in the initial phase (phase I); V0 = 567.74(6) Å3, B0 = 12.79(9) GPa, B′0 = 4 (fixed) in the high-pressure phase (phase II). These parameters indicate that the compressibility of 4-aminobenzonitrile crystals is reduced after high-pressure phase transition.
For further studying the mechanism of this high-pressure phase transition, we investigated the high-pressure Raman spectra of 4-aminobenzonitrile powder crystals. The point group symmetry of the 4-aminobenzonitrile crystal is C2h (2/m). The mechanical representation of this symmetry is
M = 45Ag + 45Au + 45Bg + 45Bu |
showing 3 acoustic modes
Γacoustic = Au + 2Bu |
and 177 optic modes
Γoptic = 45Ag + 44Au + 45Bg + 43Bu |
Group-theoretical analysis of the vibrations shows that, among the 177 optical modes, the Raman-active modes belong to the 45Ag + 45Bg symmetry and the infrared-active modes belong to the 44Au + 43Bu symmetry. Some of the Raman modes could not be observed in our experiments because of the weak intensities and limited splitting. The assignments for the Raman modes of 4-aminobenzonitrile are based on the reported literature (Table S2†).46
Fig. 4a depicts the changes in the external modes of the Raman spectra (40 to 200 cm−1) in the pressure range from 0 to 1.0 GPa. At the ambient condition, the external modes consist of six peaks (54, 64, 82, 120, 169 and 98 cm−1). As shown in Fig. 5a, the blue shifts of all the external modes during the compression indicate that the intermolecular interactions were enhanced, which was derived from the reduction of intermolecular distance.18,47 When the pressure reached 0.2 GPa, the original six external modes changed to seven. This phenomenon indicates that the intermolecular interactions were changed. Meanwhile the crystal structure was likely to transform into in a lower symmetry phase.48 Additionally, the external modes showed regular blue shifts after the phase transition below 1.0 GPa without abrupt changes.
Fig. 5 Raman shifts of 4-aminobenzonitrile from 1 atm to 1.0 GPa: (a) 40 cm−1 to 200 cm−1, (b) 200 to 1300 cm−1, (c) 1500 to 2300 cm−1, (d) 3010 to 3230 cm−1, (e) 3370 to 3490 cm−1. |
The internal Raman modes can reflect the changes of molecular vibrations, which help to study the chemical environment around the molecular groups. From 1 atm to 1.0 GPa, the high-pressure Raman spectra of the 4-aminobenzonitrile powder crystals in the range of 200 to 1300 cm−1, 1500 to 2300 cm−1 and 2900 to 3600 cm−1 are shown in Fig. 4b–d, respectively. The evolutions of Raman shifts of 4-aminobenzonitrile from 1 atm to 1.0 GPa in these regions are shown in Fig. 5b–e. From 1 atm to 0.2 GPa, most internal modes moved to the high frequency regions, indicating that the vibrations of most chemical groups on 4-aminobenzonitrile molecules were enhanced under high pressure.49,50 The blue shifts of C–H and N–H stretching modes indicate the initial N–H⋯N interactions are even weaker than normal weak hydrogen bonds, which usually show red shifts under compression.36 When the pressure reached 0.2 GPa, the ph–N in-plane bending, ring CC in-plane def., ring CH out-plane bending, ring breathing, ring CH in-plane bending, νs(ph–CN), CN stretching, NH2 scissoring, ring CC stretching, C–H stretching and N–H stretching modes showed slightly discontinuous shifts. This phenomenon indicates phase I and phase II have similar molecular arrangement and conformation. Thus, the changes of internal modes were weak at the beginning of this phase transition.15,16 However, the blue shifts of these Raman modes indicate that each chemical group especially the benzene ring suddenly shrank. The increase of the vibrational frequency of CH in-plane bending mode reflects the reduction of dihedral angle between the amino group and benzene ring,46 resulting from the planarity of molecular conformation under high pressure. The red shift of NH2 scissoring mode and the blue shifts of C–H stretching and N–H stretching modes indicate that the C–H and N–H bonds were shortened and distorted in the process of phase transition.51,52
As the pressure was continuously increased up to 6.1 GPa, the new C–H and N–H stretching modes started separating at 1.1 GPa (Fig. 6a and b). Meanwhile several new external modes also emerged beyond 1.1 GPa (Fig. 8a), but the ADXRD patterns moved regularly to higher angles without abrupt changes in this pressure range (Fig. 2b). These results indicate the phase transition was completed at 1.1 GPa and the crystal structure was just contracted in the same symmetry as phase II at higher pressures up to 6.1 GPa. The newly generated C–H stretching modes indicate that the chemical environment surrounding the benzene ring changed. The blue shifts of these two new C–H stretching modes indicates that the C–H bonds on the benzene ring became shorter as the pressure was increased. The vibrational frequency of the C–H bonds was enhanced when the benzene ring shrank. It is noteworthy that three new N–H stretching modes emerged near the original N–H stretching modes, and the two of these new peaks showed red shifts as the pressure rose (Fig. 6c). According to reported literatures, these results indicate that new weak N–H⋯N hydrogen bonds formed in the high-pressure phase transition, and then these new hydrogen bonds were enhanced by further compression.35,36,52 Meanwhile the splitting of N–H stretching modes is attributed to the lower symmetry in phase II, which is derived from distortion of amino groups in the formation of N–H⋯N hydrogen bonds. The formation of these new weak N–H⋯N hydrogen bonds also corresponds to the presence of several new external Raman modes in Fig. 7a. Since the red shifts of N–H stretching modes with the pressure was observed only after the phase transition (Fig. 6c) and the initial distance of H⋯N was longer than the empirical value of H⋯A of weak hydrogen bonds,1 the N–H⋯N interaction at the ambient condition was weaker than the weak hydrogen bond. In addition, Raman spectra of 4-aminobenzonitrile at 1 atm and the released samples in Fig. S3† indicate this high-pressure phase transition is reversible. The diffraction peaks released from 20.3 GPa broadened but were substantially the same as the initial ones (Fig. S4†). This also demonstrates that this high-pressure phase transition is reversible in the 20.3 GPa pressure range.
When the sample was subjected to high pressure, the lattice was compressed. Meanwhile the molecular packing was enhanced, leading to the gradual increase of the free energy. As the pressure shortened the distance between molecules, the abrupt changes of the molecular conformation and molecular arrangement of 4-aminobenzonitrile occurred to release the increasing free energy, leading to the phase transition of the crystal structure. When the phase transition occurred, the symmetry of the crystal was abruptly lowered, and the collapse of the volume was about 9.18% (Fig. 3b). At the same time, the amino group, the benzene ring and the cyano group on the 4-aminobenzonitrile molecules were suddenly contracted to adapt the tighter volume. The amino groups were slightly twisted with the distortion of N–H⋯N interactions. The new molecular arrangement shortened the distance of H⋯N between adjacent amino and cyano moieties, which led to the formation of new N–H⋯N weak hydrogen bonds. Then, as the pressure was increased continuously, N–H bonds of the new weak hydrogen bonds elongated, resulting in the red shifts of N–H stretching modes. This phenomenon confirms the previous analysis of the formation and enhancement of weak hydrogen bonds under high pressure.35,36
To understand the changes of the intermolecular interactions in 4-aminobenzonitrile crystals under high pressures, ab initio calculations were performed by using pseudopotential plane wave methods. The calculated crystal constants in Fig. S5a† have the similar compressibility with the ADXRD results. Although it is difficult to calculate the phase transition by geometric optimization, the second-order Birch–Murnaghan equation of the calculated results before and after 0.9 GPa are different (Fig. S5b†). This phenomenon is corresponding to the result that the phase transition was complete at about 1.0 GPa. Fig. 8b–d depict the Hirshfeld surfaces for 4-aminobenzonitrile at ambient pressure, 0.9 GPa and 6.0 GPa, respectively. The blue regions on the Hirshfeld surfaces reflect long contacts, whereas the red regions are corresponding to short contacts.53 Fingerprint plots are also utilized to compare the changes in molecular packing in Fig. 9. The decreased maximum values of de between ambient pressure (2.435 Å) and 6.0 GPa (2.063 Å) indicate the long contacts are shortened under high pressure. The two “spikes” in these three plots represent N–H⋯N hydrogen bonds. The distance of N–H⋯N hydrogen bond was reduced quickly at 0.9 GPa, which is consistent with the formation of N–H⋯N hydrogen bond and the finish of the phase transition. In Fig. 9b, the single N–H⋯N hydrogen bond extends down to (di, de)=(0.88 Å, 1.28 Å), corresponding to a hydrogen-bonded distance of 2.16 Å. From 0.9 to 6.0 GPa, the decrease of the blue regions and increase of the red regions indicate the intermolecular contacts were shortened at high pressure. The region marked by the red arrow as shown in Fig. 8b is corresponding to the amino group. The obvious increase of red colour in this region from 0.9 GPa to 6.0 GPa (Fig. 9c and d) indicates the enhancement of the N–H⋯N hydrogen bond.
Fig. 9 Fingerprint plots for 4-aminobenzonitrile at (a) ambient pressure, (b) 0.9 GPa and (c) 6.0 GPa. |
Footnote |
† Electronic supplementary information (ESI) available: The Raman spectra of 4-aminobenzonitrile and 4-aminobenzonitrile + silicone oil at 1 atm, the Pawley refinement of the diffraction pattern of 1.6 GPa, the assignments of the major Raman bands of 4-aminobenzonitrile, released Raman spectra and ADXRD patterns, reduced lattice constants and unit volume of calculated results. See DOI: 10.1039/c8ra00020d |
This journal is © The Royal Society of Chemistry 2018 |