An insight into improper hydrogen bond of C-H···N type in complexes of chloroform with hydrogen cyanide and its flouro derivative

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TẠP CHÍ KHOA HỌC TRƯỜNG ĐẠI HỌC QUY NHƠN Một cách nhìn mới về phản liên kết hydro C-H···N trong các phức của chloroform với hydrogen cyanite và dẫn xuất fluoride Phan Đặng Hồng Nhung1, Huỳnh Thanh Nam1,2, Nguyễn Tiến Trung1,* Phòng Hóa tính toán và mô phỏng, khoa Khoa học tự nhiên, Trường Đại học Quy Nhơn, Việt Nam 2 Khoa Khoa học vật liệu và kỹ thuật, Đại học Quốc gia Chungnam, Daejeon, Hàn Quốc 1 Ngày nhận bài: 21/08/2019; Ngày nhận đăng: 22/09/2019 TÓM TẮT Các tương tác không cộng hóa trị của liên kết hydro trong các phức của chlorofrom với hydrogen cyanite và dẫn xuất fluoride đã được nghiên cứu kỹ bằng cách quét bề mặt năng lượng thế năng. Các phức của cả hai hệ thống được nghiên cứu cho kết quả đều thuộc liên kết hydro chuyển dời xanh khi đạt cấu trúc hình học bền. Tất cả các hệ thống đều trải qua sự rút ngắn liên kết C-H khi ở khoảng cách xa. Ở khoảng cách N···H cụ thể, liên kết C-H của phân tử CHCl3 trong các phức chất với FCN có xu hướng chuyển dời xanh nhiều hơn so với liên kết hydro trong phức CHCl3···HCN. Các phân tích SAPT2+ cho thấy tương tác tĩnh điện là thành phần chính giúp ổn định liên kết hydro C-H···N, nhưng không xác định được sự chuyển dời xanh của tần số kéo dài C-H sau khi tạo phức. Đáng chú ý, kết quả thu được cho thấy lực phân tán đóng vai trò quan trọng trong việc kiểm soát sự chuyển của liên kết hydro. Từ khóa: Liên kết hydro, chuyển dời xanh, phân tán, tĩnh điện, SAPT2+. Tác giả liên hệ chính. Email: nguyentientrung@qnu.edu.vn * Tạp chí Khoa học - Trường Đại học Quy Nhơn, 2020, 14(1), 15-24 15 JOURNAL OF SCIENCE Q U Y N H O N U N I V E RS I T Y An insight into improper hydrogen bond of C-H···N type in complexes of chloroform with hydrogen cyanide and its flouro derivative Phan Dang Hong Nhung1, Huynh Thanh Nam1,2, Nguyen Tien Trung1,* Laboratory of Computational Chemistry and Modelling, Faculty of Natural Science, Quy Nhon University, Vietnam 2 Department of Materials Science and Engineering, Chungnam National University, Daejeon, Korea 1 Received: 21/08/2019; Accepted: 22/09/2019 ABSTRACT Non-covalent interactions in term of hydrogen bond in complexes of chloroform with hydrogen cyanide and its fluoride derivative were investigated thoroughly by scanning the potential energy surface. The complexes of both examined systems show blue-shift at their most stable geometries. All of systems experience the contraction in C-H bond length at long distances. At specific RN-H distance, the C-H bond of CHCl3 molecule in complexes with FCN tends to be more blue-shifted than one in connection with HCN counterpart. The SAPT2+ analyses reveal that electrostatic interaction is the major component which stabilizes the C–H···N hydrogen bond, but does not determine the blue shift of C-H stretching frequency following complexation. Remarkably, the obtained results show that the dispersion force plays a crucial role in controlling the shifting of the hydrogen bond. Keywords: Hydrogen bond, blue-shift, dispersion, electrostatic, SAPT2+. 1. INTRODUCTION Hydrogen bond (H-bond) is inevitably a crucial non-covalent interaction acquiring massive attention during the past decades. In standard textbooks,1-3 the bond is usually represented in the form of A-H···B. A is an atom or a group whose ability is to draw electron density from the hydrogen atom, and A-H plays as a proton donor, while B is a fragment with excessive electron cloud served as a proton acceptor. Initially, H-bond was characterized by an A-H lengthening, concomitant red-shift in its frequency and an enhancement in IR intensity. There are two well-recognized fashions which can thoroughly explain the underlying mechanism of such bond. The first explanation is based on the effect of the electrostatic component in the presence of B,4,5 while the alternative is developed on the contribution of charge transfer effect from B to A-H bond.6-11 However, the controversial debates have been triggered since the discovery of another type of interaction which bears totally opposite features than the above-mentioned bond. This interaction, which was later named improper or blue-shifting hydrogen bond, is associated with a contraction in A-H bond length, an increase in its stretching vibrational frequency and a decrease in spectroscopy intensity.12-17 Up to now, although there have been a number of proposed arguments Corresponding author. Email: nguyentientrung@qnu.edu.vn * 16 Journal of Science - Quy Nhon University, 2020, 14(1), 15-24 JOURNAL OF SCIENCE Q U Y N H O N U N I V E RS I T Y in order to explain the origin of this H-bond, no interpretation achieves consensus among scientists universally. Some authors proposed that the blue-shifting effect was derived from the reorganization of the host molecule. Such restructuring can be consequences of the charge transfer contribution,13 or the rehybridization.18 Meanwhile, others managed to justify the nature of H-bond as a balance of opposing interactions.19, 20 For a long time, our group has pursued another way of explanation for this bond of interest. Among hydrogen bonded systems, we have paid more attention to the interactions of C-H donors with various proton acceptors. This is due to the fact that C-H type hydrogen bond is of great importance in biological systems;21-23 gaining understanding about them, thus, can pave the way for having more insight into our bodies. Moreover, this type of H-bond is categorized into the pro-improper donor, according to Joseph and Jemmis,20 whose shifts in C-H bond strongly depend on the nature of proton acceptors. In our article published in 2017,24 we found that the stabilities of the complexes are influenced by the gas phase basicity of the donor,24 and the polarization of the C-H bond. Specifically, the majority of the interactions between halofrom and acceptor proton Y are CHF3 for blue-shifted hydrogen bond while CHBr3 gives mainly redshifted hydrogen bond. As for CHCl3 gives both of H-bond types, therefore the polarity of the C-H bond in the CHX3 monomers increases in substituted order of X in going to from F to Cl and then to Br. Thus, we carried out fixing the distance N···H and optimized the geometric parameters of the complexes. Besides, for a specific donor, the basicity is directly associated with the change in C-H bond length. Therefore, we held a belief that as the dependence of C-H bond length on the Lewis base’s origin was clarified, they must be interactions from the acceptor, not internal changes in donor’s structure, controlling the shift of the C-H covalent bond. It prompted a need to investigate the role of single interactions that contribute to the stability of a dimer upon complexation. In the above study and another previous work, we conducted SAPT calculations in order to decompose the total interaction energy into four physically meaningful forces, namely electrostatic, dispersion, induction, and exchange. This way of analysis has been proved to provide reliable energy decomposition results.26 Furthermore, we reported some significant comments on the role of energy components to H-bond, especially the importance of dispersion in blue-shifting systems.25 Hence, in this work, we utilized SAPT as a productive tool to examine the change in contributions of these interactions during the complex formation comprehensively and expected to shed light on the nature of blueshifting hydrogen bond. 25 2. COMPUTATIONAL DETAILS All the ab initio calculations were performed by the Gaussian 09 package.27 For the purpose of the present work, we constrained the distance between a proton donor and an acceptor RN-H (RN-H = 1.7 – 3.5 A) and the C3v symmetry. The remaining parts of complexes were optimized at MP2/6-311++G(3df,2pd) level of theory. Stretching frequencies are calculated at the same level in order to investigate the shift of C-H bond’s stretching frequency. Single point energy (SPE) and basis set superposition error (BSSE) via the counterpoised correction of Boys and Bernadi28 for all the monomers and complexes are obtained at the CCSD(T)/6311++G(3df,2pd)//MP2/6-311++G(3df,2pd) level. Interaction energies are estimated as the difference in energy between complexes and their fragments, corrected for both of ZPE and BSSE (∆E*). Topological parameters of complexes at the bond critical points (BCPs) were computed using the AIM2000 software.29 The SAPT2+ calculations for the complexes were applied with the aug-ccpVDZ basis set using Psi4 software.30 The total intermolecular interaction energy was separated into five fundamental components which are so-called electrostatic (Eelst), dispersion (Edisp), Journal of Science - Quy Nhon University, 2020, 14(1), 15-24 17 TẠP CHÍ KHOA HỌC TRƯỜNG ĐẠI HỌC QUY NHƠN induction (Eind), exchange (Eexch) and δEHF, where δEHF contributing to the interaction energy includes all third and higher-order induction and exchange-induction terms. The total intermolecular interaction energy is calculated as shown in equation: ESAPT2+ = Eelst + Eind + Eexch + Edisp + δEHF(1) III. RESULTS AND DISCUSSION 3.1. Changes of the C-H bond length and its stretching frequency The changes in C-H bond length and the corresponding stretching frequency in the two complex systems are presented in Table 1. The ∆r value is negative at large separation and decreases until the minimum is reached, then increases to positive ones, indicating that the C-H shortening occurs over the long distances and the elongation occurs at short range. The change of its stretching frequency further supports this observation as ∆ν value is positive at large distances and gradually increases until reaching its maximum value and then decreases to negative values. The shift from blue- to redshifting when the proton acceptor comes closer is similar to some previous studies.20, 31, 32 Table 1. Changes in bond length (∆r(C-H), in Å), stretching vibrational frequency (∆νC-H in cm-1) of the C–H bond and the interaction energy corrected by both ZPE and BSSE (∆E* (kJ.mol-1)) RN-H (Å) 1.7 1.9 2.1 2.3 2.5 2.7 2.9 3.1 3.3 3.5 ∆r(C-H) 0.01599 0.00497 0.00063 -0.00083 -0.00115 -0.00110 -0.00097 -0.00085 -0.00075 -0.00064 CHCl3···NCH ∆ν(C-H) -138.53 -28.08 12.24 21.43 19.3 15.18 12.04 10.09 8.77 7.62 ∆E* 14.07 -3.15 -10.04 -12.00 -11.68 -10.57 -9.04 -7.61 -6.38 -5.36 Table 1 shows that, at long distances, the C-H bond in CHCl3···NCF decreases much more than that of the NCH, and also fewer increases at short range. Specifically, the contraction of the C-H bond in CHCl3 increases from 0.00067 Å to 0.00126 Å when interacting with FCN. These values are about 0.000040.00023 Å more than those of the remaining system, where the C-H bond is shortened ca. 0.00064-0.00115 Å. In both systems, the C-H bond lengths reach minima at RN-H = 2.5 Å. The complexes, then, exhibit increases in C-H bond lengths when the acceptor comes closer. The CHCl3···NCH system shows an increase at ca. 0.00024-0.00187 Å more than the CHCl3···NCF system. Overall, the blue shift is more preferred in the FCN system as compared to the HCN one. The level of contraction and elongation of C-H 18 ∆r(C-H) 0.01412 0.00402 0.00014 -0.00107 -0.00126 -0.00116 -0.00100 -0.00087 -0.00076 -0.00067 CHCl3···NCF ∆ν(C-H) -112.05 -14.30 19.40 25.07 21.06 15.97 12.97 10.26 8.92 7.80 ∆E* 15.02 -2.28 -9.11 -11.09 -10.82 -9.74 -8.30 -6.96 -5.80 -4.85 length bond is different, when the complexes are formed by the electrostatic energy and the ability to electron density transfer from n(N) lone pair to the σ*(C-H) orbital. Both of factors depend on the increase of the gas phase basicity at the N site of these proton acceptors. Indeed, we calculated the proton affinities at N sites in two acceptors at CCSD(T)/6-311++G(3df,2pd)// MP2/6-311++G(3df,2pd) and the obtained results show that the PA values at N sites in FCN (679 kJ.mol-1) is smaller than that in HCN (700 kJ.mol-1). 3.2. Interaction energy, and its relation with N···H intermolecular distance The interaction energies taken into account both ZPE and BSSE (∆E*) calculated at the CCSD(T)/6-311++G(3df, 2pd)//MP2/6-311++G (3df, 2pd) level are also gathered in Table 1. In Tạp chí Khoa học - Trường Đại học Quy Nhơn, 2020, 14(1), 15-24 JOURNAL OF SCIENCE Q U Y N H O N U N I V E RS I T Y general, the interaction energies lie in the range from -5.36 to -12 kJ.mol-1 and from -4.85 to -11.09 kJ.mol-1 corresponding to the interactions of HCN and FCN with CHCl3. At the N···H distance is 2.3 Å which the interaction energies are the most negative for the two complexes. In order to clearly see the relationship between the changes in the C-H bond length and the interaction energy, we plot correlations as shown in Figure 1. The most stable complexes experience blue-shifting with the intermolecular distance between the proton donor and proton acceptor to be in the range of 2.1 – 2.3 Å. Flexible optimization results at MP2/6-311++G(3df,2pd) level confirm this observation. Specifically, at the equilibrium geometries, the distance of N···H contacts is 2.21 Å in CHCl3···NCH and CHCl3···NCF dimers. This result is in accordance with a recent study investigating the interaction of two molecules in the Ar matrix.33 Additional examination on the effect of the interaction energy on the shift from blueto red- shifting. We make a comparison based on the value of interaction energies among the checked systems as presented in Figure 2. Figure 2 indicates that the interaction energies are negative when the N···H distances are in the range of 1.9 ÷ 3.5 Å and they get the positive values with RN-H smaller than 1.9 Å. Namely, the interaction energies decrease until reaching its minimum value at long distance and then gradually increase at short range when the N···H distance continues decreasing. On the other hand, at the same distance, the durability of the CHCl3···FCN complexes is smaller than the CHCl3···HCN complexes, which is consistent with previous reports.24, 34-36 The difference in the stability of the two systems can be due to the higher gas-phase basicity of HCN, whose effect was proposed in our previous study.24 CH HCl3···NCH Figure 2. Comparison of the interaction energy between two systems 3.3. AIM analysis In an attempt to further understand the properties of C-H···N hydrogen bond in the complexes, we carried out QTAIM analysis for the complexes at MP2/6-311++G(3df,2pd). Results of topological geometries as given in Table 2 CH HCl3···NCF show that the bond critical point (BCP) appears at a very long distance. In general, when XCN Figure 1. Relationship between the interaction Relationsh hip between th he interaction en nergies and ∆rr(C-H) in the coomplexes: CH HCl3···HCN annd comes closer to CHCl3, the electron density at energies and ∆r(C-H)CH inHCl the complexes: CHCl3···HCN ···FCN 3 and CHCl3···FCN the BCP of N···H contact in each system rises Journal of Science - Quy Nhon University, 2020, 14(1), 15-24 19 TẠP CHÍ KHOA HỌC TRƯỜNG ĐẠI HỌC QUY NHƠN linearly in the range of 0.0010-0.0519 au. There is virtually no significant difference in the electron density at the BCP of the intermolecular contact in the two systems with the same N···H distance. Nevertheless, for the alike N···H distance the electron density at BCP of N···H contact is slightly larger for CHCl3···NCH than CHCl3···NCF. Table 2. The topological parameters at BCPs of the N···H contacts at MP2/6-311++G(3df.2pd) and the individual hydrogen bond energy (EHB) CHCl3···HCN dHB (Å) 1.7 1.9 2.1 2.3 ρ(r)(au) 0.0519 0.0326 0.0207 0.0134 0.0087 0.0057 0.0038 0.0025 0.0016 0.0010 ∇2(r)(au) 0.122 0.099 0.071 0.019 0.006 H(r) -0.0115 -0.0016 0.0014 0.0016 0.0012 0.0009 0.0007 0.0005 0.0004 0.0003 EHB -70.8 -36.9 -19.6 -3.9 -0.9 ρ(r)(au) 0.0510 0.0319 0.0202 0.0131 0.0085 0.0056 0.0036 0.0024 0.0016 0.0010 ∇2(r)(au) 0.123 0.099 0.070 0.019 0.006 H(r) -0.0109 -0.0013 0.0015 0.0018 0.0013 0.0009 0.0007 0.0005 0.0004 0.0003 EHB -69.1 -3.8 -0.9 0.047 -11.0 2.5 0.030 -6.5 2.7 2.9 0.013 -2.5 3.1 0.009 -1.5 3.3 3.5 0.004 -0.6 CHCl3···FCN (kJ.mol-1) -35.9 -19.1 0.047 -10.7 0.029 -6.3 0.012 -2.4 0.008 -1.5 0.004 -0.5 (kJ.mol-1) The Laplacians ( ∇ 2 (r)) and H(r) at BCPs fall within the criteria of the hydrogen bond formation. As a result, the C-H···N intermolecular interactions in the complexes are considered as hydrogen bonds. To be more specific, ∇ 2 (r) of all systems is greater than 0. When the intermolecular distance of the two molecules decreases, the ∇ 2 (r) increases from 0.004 to 0.122 au in CHCl3···NCH and from 0.004 to 0.123 au in CHCl3···FCN. H(r) at BCP of N···H contact in two systems gives a value larger than 0 at a distance larger than 2.0 Å, while for RN-H = 1.7 and RN-H = 1.9 Å, H(r) values are negative. Hence, it can be concluded that the interaction formed between proton donor and acceptor at distances of larger than 1.9 Å are weak hydrogen bonds and the others are moderate ones that take a part of covalent nature. 3.4. Role of energy component To elucidate the role of each energy component in the red- or blue-shifting of hydrogen bond in the complexes, SAPT2+ analyzes at the aug-ccpVDZ basis set were performed for the optimized 20 structures at the MP2/6-311++G(3df,2pd) level. The value of the energy components as well as the contribution percentage to the stability of the complexes at each specified distance are shown in Table S1-S2 in Supporting Information. In all of the energy components, there are three main energy components, including electrostatic, dispersion and induction, contribute to stability of complexes, whereas exchange interaction causes a decrease in complex durability. Two examined systems share similar patterns in the contributions of interaction forces. The electrostatic energy component plays a dominant role in the stabilization of these complexes, especially at large distances. Thus, for the CHCl3···NCH system, as RN-H decreases, the electrostatic energy decreases from -4.90 to -62.6 kJ.mol-1, which accounts for 47-76% of the total stabilizing energy. Meanwhile, this type of forces is responsible for about 46-75% in the intermolecular interactions of CHCl3 with NCF. For further analysis, we plot the correlations of the contribution percentage of Tạp chí Khoa học - Trường Đại học Quy Nhơn, 2020, 14(1), 15-24 JOURNAL OF SCIENCE Q U Y N H O N U N I V E RS I T Y energy components and the changes in C-H bond length with respect to the intermolecular distance. Particularly, those of electrostatic and dispersion component are presented in Figure 3, and that of induction term is illustrated in Figure S1 of Supporting Information. a b Figure 3. Relationship between %Eelst, %Edisp and ∆r in: a) CHCl3···HCN and b) CHCl3···FCN As shown in Figure 3, while the ∆r significantly fluctuates during the formation of complexes, the contribution percentage of the electrostatic component in stabilizing energy decreases monotonously. This indicates that such correlation gives no clue to determine when the interaction turns from blue- to redshifting hydrogen bond. In other words, even though playing a pivotal role in stabilizing the Similar circumstances were seen in Figure S1. The induction energy increases linearly in both of its values and its percentage contribution to the stabilizing energy. In studied complexes, the induction energy contributes from 5-7% at RN-H = 3.5 Å to 32-33% at RN-H = 1.7 Å. Although this force is also proposed to be partly responsible for the red-shifting behaviors to some extent,24 it, here, shows no significant relationship with changes in the shift of C-H stretching vibrational frequencies. Therefore, we can assume that the role of this interaction in controlling the change of the C-H bond is minor and can be ignorable. Remarkably, we can see a direct connection when considering the relationship between dispersion energy and the change in the C-H bond length. It is obvious from Figure 3 that when the contribution percentage of dispersion interaction increases, the shortening of the C-H bond length increases as well and vice versa. The former trend occurs when the donor-acceptor range decreases from 3.5 to 2.5 Å in the complexes of HCN and FCN, while the latter happens in the remaining regions, where the two fragments come closer. Also, there are coincident extreme points obtained in dispersion contribution line and the C-H bond length variation line in all systems, indicating that the blue-shifting effect reaches its maximum when the participation of dispersion in the stabilizing energy is highest. Thus, it is reasonable to conclude the vital importance of the dispersion in the blueshifting hydrogen bond. Further examination on the effect of the dispersion term on the shift of hydrogen bonds is considered. We make a comparison based on the contribution of such interaction among the examined systems, which is demonstrated in Figure 4. complexes, electrostatic is not the key factor that identify the shift of hydrogen bond. Journal of Science - Quy Nhon University, 2020, 14(1), 15-24 21 TẠP CHÍ KHOA HỌC TRƯỜNG ĐẠI HỌC QUY NHƠN hydrogen bond. However, it is noteworthy that dispersion term plays an important role in change from blue- to red- shifting hydrogen bond for the complexes of CHCl3 with HCN and FCN. Our work will prompt further exploration of the role of dispersion energy in the red- and blue-shifting hydrogen bond for a better understand of the types of bond. Figure 4. Comparison of the % Edisp between two systems In the CHCl3···HCN complexes, the highest percentage of dispersion component is about 24%. Meanwhile, the largest participation of dispersion term reaches at around 27% in the complexes of FCN. The contribution of dispersion energy, thus, increases in the order of HCN < FCN proton acceptor. Remarkably, this order is of great consistency with the pattern of the increase of blue-shifting effect, which has been well described in Section 3.1. Again, it is evident that the greater the dispersion interaction is, the higher the blue-shifting of the hydrogen bond is. 4. CONCLUDING REMARKS The stable complexes of chloroform with cyanide derivatives XCN (X= H, F) were thoroughly examined at the CCSD(T)/6-311++G(3df,2pd)// MP2/6-311++G(3df,2pd) level of theory. The stability of the complex of chloroform with hydrogen cyanite is larger than its flouro derivative at the same donor-acceptor distance. The obtained results show that the change from blue- to red-shift of C-H stretching frequency in the C-H···N hydrogen bond increases in order of FCN < HCN derivative, which results from the increase in the gas phase basicity at N site. 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